KR20200010850A - Removable remote control hyperbaric oxygen treatment system based on platform - Google Patents

Abstract

The present invention relates to a portable and remotely managed high-pressure oxygen treating system based on a platform, capable of an immediate response by being transferred to an accident site, which comprises: a high-pressure oxygen chamber having an air supply terminal end and a discharge valve; a supply chamber having an air storage tank and an oxygen storage tank installed therein; an oxygen control valve controlling an oxygen flow rate; a machine chamber having a compressor, a generator, and a control unit; a measurement unit having a temperature sensor, a humidity sensor, and a concentration sensor; and a management platform.

Description

Removable remote control hyperbaric oxygen treatment system based on platform

The present invention relates to a platform-based mobile remote management hyperbaric oxygen treatment system.

Hyperbaric oxygen treatment is a treatment method that induces the medical treatment effect by inhaling 100% oxygen to the patient above 1.4 atm. High concentration oxygenation occurs in plasma and body fluids other than hemoglobin, and the treatment is continued by maintaining high oxygen concentration in peripheral tissues of edema or narrowed blood vessels. Accumulation of therapeutic effects can lead to collagen formation, fibroblast formation, and tissue recovery after ischemia through fibroblast activity.

Hyperbaric Oxygen Therapy is a device for conducting hyperbaric oxygen therapy. It is a device that sequentially pressurizes or decompresses up to 2 ~ 6 atmospheres higher than atmospheric pressure in the space where the whole body can enter. It can be classified as a multi-use hyperbaric therapy.

The hyperbaric oxygen treatment device can be applied to the treatment of diving disease, gas poisoning treatment, diabetic foot ulcer treatment, edema reduction, wound treatment after surgery, brain related disease treatment, etc., and can have effects of fatigue recovery and skin beauty, and various types of wounds. It is being used for treatment, and its scope of use is expanding in surgery, orthopedics, plastic surgery and the like.

However, there is a problem that it is difficult to respond in case of emergency disaster due to the limited supply of hyperbaric oxygen treatment device. Currently, there are only 21 treatment centers identified in the Korean High-Pressure Medical Association, with 13 single-person devices and 12 multi-person devices installed. In cases where there are no high-pressure oxygen treatment centers, in case of an emergency such as a marine accident or a large fire, patient transportation to the treatment center takes a long time, resulting in a loss of golden time.

In addition, the hyperbaric oxygen therapy device has a problem that it is difficult to install in a facility and hospital lacking space due to a large volume. That is, the equipment required for operating the hyperbaric oxygen treatment device such as a chamber body, a control console, an air supply device, and an oxygen supply device has difficulty in introducing equipment in many facilities and hospitals due to its large weight and volume.

In addition, even if it is sufficient to install spatially, a large amount of introduction costs are incurred in dismantling the outer wall of the building during introduction. In addition, there are hospitals that cannot be installed due to deterioration of the building itself, and there is a difficulty in overseas export due to the large volume of existing hyperbaric oxygen treatment equipment and the need for additional installation work after transportation, and the chamber body, the control console and the air supply device. Due to the location selection and the piping work according to the facility, there is a problem that it is difficult to export the existing multi-person chamber.

In addition, there is a problem in that there is a lot of additional costs in packaging and shipping, there is a lot of costs and human resources, such as equipment and packaging and unpacking installation because there is no standard container for the multi-person chamber developed in the prior art.

Therefore, it was required to develop a high-pressure oxygen therapy device remote operation control system incorporating ICT technology that can be moved in an emergency disaster, can be introduced to the external environment, and can automatically control a multi-use high-pressure oxygen therapy device.

United States Patent US7263995 Korean Registered Patent No. 0561209 United States Patent US8251057 Korean Patent No. 1725877

Therefore, the present invention has been made to solve the above-mentioned conventional problems, according to an embodiment of the present invention, by developing a portable high-pressure oxygen treatment device in the form of a container to be transported immediately to the accident site is possible, the air supply device It is possible to install faster than existing multi-person high pressure oxygen therapy device by modularized container such as oxygen supply device and control console, and to supply its own power through internal generator, and to prepare fire inside the high pressure oxygen therapy device by equipped with fire tank. The purpose of the present invention is to provide a portable high-pressure oxygen therapy device in the form of a container that can be moved in case of an emergency disaster.

According to an embodiment of the present invention, by applying a container type high pressure oxygen treatment device can be introduced into a facility that is difficult to install spatially inside the building, the container type high pressure oxygen treatment device uses space compared to the conventional circular high pressure oxygen treatment devices It is excellent in performance, and it is possible to maintain the temperature even in the external environment by installing air conditioners in the cockpit and machine room, and because there is a generator, it is possible to operate the hyperbaric oxygen therapy device through the self-power generation even in the absence of external power source. And the purpose is to provide a high-pressure oxygen therapy device in the form of a container that can be prepared for bad weather conditions and can be introduced to the outside environment by installing doors in chambers, supply rooms, machine rooms and cockpits for convenient access during periodic maintenance.

In addition, according to an embodiment of the present invention, the automatic control through the control program in the existing manual control method is possible, and through the treatment profile generation function, it is possible to support a variety of treatment profiles, the system for the registration and management of hyperbaric oxygen treatment patients in the system And, the automatic control system is easy to operate by simplifying the operation method compared to the manual control method, and provides the automatic control system of the multi-person high pressure oxygen therapy device capable of automatic control for remote operation in the absence of the high pressure oxygen therapy specialist. Its purpose is to.

In addition, according to an embodiment of the present invention, when the high-pressure oxygen treatment device is installed in the disaster site, it is possible to properly operate through communication with the specialists in the hospital and the medical staff in the field in the absence of a specialist in the field, screen mirroring Through real-time hyperbaric oxygen treatment device operating profile, gas analysis can be confirmed, enabling the internal monitoring system and voice communication of the hyperbaric oxygen treatment device, medical staff can check the patient's condition in real time, as well as the patient's condition, hyperbaric oxygen It is possible to check the amount of pressure, temperature, humidity, carbon dioxide concentration and oxygen concentration, which are the status information of the treatment device, in real time, and other necessary equipment such as generator, compressor, air-conditioning system, air storage tank, gas oxygen bottle, etc. Providing remote operation control system for hyperbaric oxygen therapy device using ICT technology It has that purpose.

On the other hand, the technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems that are not mentioned are clearly to those skilled in the art from the following description. It can be understood.

An object of the present invention, in the high pressure oxygen treatment system, the inside is pressurized by high pressure air, the oxygen is supplied to the patient through the mask, the air supply stage is supplied with air, the exhaust end for exhausting the internal air, exhaust stage A high pressure oxygen chamber having a discharge valve provided at one side; A supply chamber in which an air storage tank and an oxygen storage tank are installed; An air supply pipe for supplying air in the air storage tank into the high pressure oxygen chamber, a pressure control valve for controlling the pressure in the high pressure oxygen chamber by adjusting a flow rate of the air supplied at one side of the air supply pipe, and in the oxygen storage tank An oxygen supply pipe for supplying oxygen to the mask, and an oxygen control valve for controlling a flow rate of oxygen supplied and provided at one side of the oxygen supply pipe; A machine room connected with the air storage tank, the compressor providing a supply pressure, a generator for supplying power to the compressor, and a control unit for controlling the pressure regulating valve, the oxygen regulating valve, and the discharge valve; A pressure gauge for measuring the pressure in the high-pressure oxygen chamber, a temperature sensor for measuring the temperature in the high-pressure oxygen chamber, a humidity sensor for measuring the humidity in the high-pressure oxygen chamber, a concentration for measuring the oxygen, carbon dioxide concentration in the high-pressure oxygen chamber A measuring unit having a sensor; And a management platform having a receiving unit for receiving a value measured by the measuring unit, and a setting unit for setting an optimal control range and transmitting a control signal to the control unit. Platform-based mobile remote management hyperbaric oxygen treatment system, comprising: Can be achieved as:

The high pressure oxygen chamber, the supply chamber, and the machine room are configured in a movable container form, and a plurality of patients are accommodated in the high pressure oxygen chamber, and the arterial blood oxygen saturation, respiratory waveform, pulse rate, blood pressure, and electrocardiogram of the patient are measured. And a biometric information measuring unit, wherein the receiving unit of the management platform receives a value measured by the biometric information measuring unit.

In addition, the management platform is diagnosed by analyzing the biometric information measured by the biometric information measuring unit during treatment, the CO concentration, arterial blood oxygen saturation of the patient, and the mitochondrial oxidative stress and cell signal transmission change measured before and after the treatment, respectively. Analysis means for forming and storing data; And a database for classifying the measured values and the diagnosis data by DB for each patient and disease type.

And a connection pipe connecting the oxygen supply pipe and the air supply pipe, and a control valve provided at one side of the connection pipe, wherein the setting unit includes a treatment time, an oxygen supply cycle, an oxygen concentration, and a pressure based on the diagnosis data. , By setting an optimum control range of temperature and humidity, and transmitting a control signal to the controller.

In addition, a speaker for directing and outputting sound of a predetermined frequency band to the eardrum of the patient, a microphone for receiving the reflected wave reflected from the eardrum of the patient, the magnitude of the output sound and the component corresponding to the sound of the reflected wave A measurement unit for measuring admittance in the tympanic membrane of the patient based on size, the receiving unit receiving the admittance measured in the measuring unit, and the setting unit receiving the pressurized pressure in the chamber based on the admittance The control signal may be determined and transmitted to the controller.

The measuring unit measures the admittance of each of the plurality of patients, and the setting unit maintains the pressurization when the patient reaches the pressure equilibrium state based on the patient having the minimum admittance during the pressing, and does not reach the pressure equilibrium state. If not, the pressurization may be stopped for a certain time, and the control signal may be transmitted to reduce the pressure when the pressure equilibrium state is not reached even during the predetermined time.

In addition, the control unit may control the control valve to supply oxygen to the set oxygen concentration, it may be characterized in that the control to close the oxygen control valve and open the control valve during the oxygen brake time.

And one side of the air supply pipe, characterized in that the silencer having a silencer, and a porous packing material located in the noise housing to reduce the noise of the compressor.

In addition, the air supply pipe is provided on one side of the cooling device for cooling the supplied air, the control unit may be characterized in that for controlling the cooling device so that the temperature in the chamber is maintained in a set range.

And at least one of a suction fan provided at one side of the chamber and sucking air to the inside through an inlet, a CO 2 absorbent for absorbing carbon dioxide in the sucked gas, a moisture absorber for absorbing moisture, and a dust filtration filter. The controller may further include: The controller may control the controller based on the values measured by the concentration sensor and the humidity sensor so that the carbon dioxide, oxygen concentration, and humidity in the chamber are maintained within a set range. have.

In addition, by connecting to the management platform through a user terminal, it may be characterized in that for monitoring the value measured by the measuring unit, the value measured by the biometric information measuring unit, the diagnostic data.

According to an embodiment of the present invention according to the container-type portable high pressure oxygen treatment device that can be moved in case of an emergency disaster, a container type portable high pressure oxygen treatment device is developed and transported to the accident site for immediate response, and an air supply device and oxygen Container type modularization of supply device, control console, etc. enables faster installation than existing multi-pressure high-pressure oxygen therapy device, self-power supply through internal generator, and firefighting tank to prepare for fire in the high-pressure oxygen therapy device Has

According to the container-type high pressure oxygen treatment device that can be introduced into the external environment according to an embodiment of the present invention, by applying a container-type high pressure oxygen treatment device can be introduced into a facility that is difficult to install spatially inside the building, container-type high pressure Oxygen therapy device has excellent space utilization compared to the conventional circular high pressure oxygen therapy devices, and it is possible to maintain the temperature in the external environment by installing air conditioners in the cockpit and machine room, and because the generator exists, It can operate high pressure oxygen treatment device, and it is possible to prepare for freezing and bad weather situation by inserting insulation material, and the doors are installed in the chamber, supply room, machine room and cockpit, so it can be easily entered and exited during periodic maintenance.

In addition, according to the automatic control system of the multi-person high pressure oxygen therapy apparatus according to the embodiment of the present invention, the automatic control through the control program is possible in the existing manual control method, and through the treatment profile generation function, it is possible to support various treatment profiles It is possible to register and manage hyperbaric oxygen treatment patients in the system, and the automatic control system can be easily operated by simplifying the operation method compared to the manual control method, and can be automatically controlled for remote operation in the absence of the high pressure oxygen treatment specialist. There is an advantage.

In addition, according to the high-pressure oxygen treatment device remote operation control system incorporating ICT technology according to an embodiment of the present invention, when a high-pressure oxygen treatment device is installed in the disaster site, a specialist and a site that resides in the hospital in the absence of a specialist in the field It is possible to perform proper operation through communication with medical staff, real-time hyperbaric oxygen treatment device operation profile, gas analysis and confirmation through screen mirroring, and internal medical monitoring device and voice communication of hyperbaric oxygen therapy device. It is possible to check the status, as well as the patient's status, the real-time information of the pressure, temperature, humidity, carbon dioxide concentration, oxygen concentration, which is the status information of the hyperbaric oxygen treatment device, and other auxiliary equipment such as generators, compressors, air conditioning systems, and air. Possible to monitor the devices necessary for operating the high pressure oxygen treatment device such as storage tank and gaseous oxygen bottle And it has a.

On the other hand, the effects that can be obtained in the present invention is not limited to the above-mentioned effects, other effects that are not mentioned will be clearly understood by those skilled in the art from the following description. Could be.

The following drawings, which are attached to this specification, illustrate one preferred embodiment of the present invention, and together with the detailed description thereof, serve to further understand the technical idea of the present invention. It should not be construed as limited.
1 is a plan view of the high-pressure oxygen chamber, supply chamber, machine room of the platform-based mobile remote management high-pressure oxygen treatment system according to an embodiment of the present invention,
Figure 2 is a perspective view of the high-pressure oxygen chamber, supply chamber, machine room of the platform-based mobile remote management high pressure oxygen treatment system according to an embodiment of the present invention,
3 and 4 is a conceptual diagram of a platform-based mobile remote management hyperbaric oxygen treatment system according to an embodiment of the present invention,
5 is a partial perspective view of a high-pressure oxygen chamber according to an embodiment of the present invention,
Figure 6 is a block diagram of a platform-based mobile remote management hyperbaric oxygen treatment system according to an embodiment of the present invention,
7 is a block diagram of a measuring unit according to an embodiment of the present invention;
8 is a block diagram of a biometric information measuring unit according to an embodiment of the present invention;
9 is a schematic diagram of biometric information management according to an embodiment of the present invention;
10 is a database block diagram of a management platform according to an embodiment of the present invention;
11 is a cross-sectional view of the air supply pipe and the connection pipe oxygen supply pipe according to an embodiment of the present invention,
12 is a cross-sectional view of a cooling apparatus according to an embodiment of the present invention,
13 is a perspective view of a regulator according to an embodiment of the present invention,
14A is a sectional view of a silencer according to an embodiment of the present invention;
14B is an exploded perspective view of a silencer according to the embodiment of the present invention;
15 is a conceptual diagram of a probe according to an embodiment of the present invention mounted on an ear of a patient;
16 is a flowchart illustrating a pressure regulating method according to an embodiment of the present invention.

The above objects, other objects, features and advantages of the present invention will be readily understood through the following preferred embodiments associated with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosure may be made thorough and complete, and to fully convey the spirit of the invention to those skilled in the art.

In the present specification, when a component is mentioned as being on another component, it means that it may be formed directly on the other component or a third component may be interposed therebetween. In addition, in the drawings, the thickness of the components are exaggerated for the effective description of the technical content.

Embodiments described herein will be described with reference to cross-sectional and / or plan views, which are ideal exemplary views of the present invention. In the drawings, the thicknesses of films and regions are exaggerated for effective explanation of technical content. Therefore, the shape of the exemplary diagram may be modified by manufacturing techniques and / or tolerances. Accordingly, the embodiments of the present invention are not limited to the specific forms shown, but also include changes in forms generated by the manufacturing process. For example, the region shown at right angles may be round or have a predetermined curvature. Thus, the regions illustrated in the figures have properties, and the shape of the regions illustrated in the figures is intended to illustrate a particular form of region of the device and is not intended to limit the scope of the invention. Although terms such as first and second are used to describe various components in various embodiments of the present specification, these components should not be limited by such terms. These terms are only used to distinguish one component from another. The embodiments described and illustrated herein also include complementary embodiments thereof.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, the words 'comprises' and / or 'comprising' do not exclude the presence or addition of one or more other components.

In describing the specific embodiments below, various specific details are set forth in order to explain the invention more specifically and to help understand. However, one of ordinary skill in the art can understand that the present invention can be used without these various specific details. In some cases, it is mentioned in advance that parts of the invention which are commonly known in the description of the invention and which are not highly related to the invention are not described in order to prevent confusion in explaining the invention without cause.

Hereinafter will be described the configuration and function of the platform-based mobile remote management hyperbaric oxygen treatment system 100 according to an embodiment of the present invention. First, Figure 1 shows a plan view of the high-pressure oxygen chamber 10, supply chamber 20, machine room 30 of the platform-based mobile remote management hyperbaric oxygen treatment system 100 according to an embodiment of the present invention. And Figure 2 shows a perspective view of the high-pressure oxygen chamber 10, the supply chamber 20, the machine room 30 of the platform-based mobile remote management high pressure oxygen treatment system 100 according to an embodiment of the present invention. In addition, Figure 3 and Figure 4 shows a conceptual diagram of the platform-based mobile remote management hyperbaric oxygen treatment system 100 according to an embodiment of the present invention. 5 shows a partial perspective view of the high-pressure oxygen chamber 10 according to the embodiment of the present invention.

Platform-based mobile remote management hyperbaric oxygen treatment system 100 according to an embodiment of the present invention according to an embodiment of the present invention is a high-pressure oxygen chamber 10, a supply room 20, a machine room 30 that is moved to the installation site as a whole And, it may be configured to include a management platform 110 provided in the hospital and the like to be the subject of remote management.

The high pressure oxygen chamber 10, the supply chamber 20, and the machine room 30 are all formed in a movable container form, which can be introduced to a facility that is difficult to install spatially inside a building, and utilizes a space as compared to a conventional circular high pressure oxygen treatment device. It has excellent characteristics. That is, by installing in a place where hyperbaric oxygen treatment is required it is possible to use immediately by connecting to the management platform 110 and communicated.

The high-pressure oxygen chamber 10 according to the embodiment of the present invention, as shown in Figures 1, 2, 5, is provided in the form of a removable container, a chair 12 and a door that can be seated by a plurality of patients 11), and configured to be pressurized by high pressure air. In addition, oxygen is supplied to the patient through the mask, and an air supply stage through which air is supplied, an exhaust stage through which internal air is discharged, and a discharge valve 26 provided on one side of the exhaust stage. The high pressure oxygen chamber 10 is configured to withstand a pressure of about 3 to 6 atm.

As shown in FIGS. 1 and 2, the supply chamber 20 may include an air storage tank 21, an oxygen storage tank 22, and a fire fighting tank 23. In addition, the air supply pipe 13 for supplying air in the air storage tank 21 into the high pressure oxygen chamber 10 and the air supply pipe 13 are provided at one side to adjust the flow rate of the supplied air in the high pressure oxygen chamber 10. A pressure regulating valve 24 for adjusting pressure, an oxygen supply pipe 14 for supplying oxygen in the oxygen storage tank 22 as a mask, and an oxygen supplying flow rate provided at one side of the oxygen supply pipe 14 It is configured to include a control valve (25).

And the machine room 30 is connected to the air storage tank 21, the compressor 31 for supplying the supply pressure, the generator 32 for supplying power to the compressor 31, the pressure control valve 24 and oxygen control The control part 33 which controls the valve 25 and the discharge valve 26 is provided. Therefore, the mobile container form is applied so that it can be immediately responded to by transporting to the accident site and installed faster than conventional multi-pressure high-pressure oxygen therapy device by modularized container such as air storage tank 21, oxygen storage tank 22, and control unit 33. It is possible to supply its own power through the generator 32 inside the machine room 30, and the fire tank 23 is provided to prepare for the internal fire.

Figure 6 shows a block diagram of a platform-based mobile remote management hyperbaric oxygen treatment system 100 according to an embodiment of the present invention. 7 shows a block diagram of a measuring unit 40 according to an embodiment of the present invention.

Platform-based mobile remote management hyperbaric oxygen treatment system 100 according to an embodiment of the present invention comprises a measuring unit 40 for measuring the environment in the various hyperbaric oxygen chamber 10 and these measured values are the control unit 33 ) And the reception unit 111 of the management platform 110.

As shown in FIG. 7, the measurement unit 40 includes a pressure gauge 41 for measuring the pressure in the high pressure oxygen chamber 10, a temperature sensor 42 for measuring the temperature in the high pressure oxygen chamber 10, and high pressure oxygen. The humidity sensor 43 for measuring the humidity in the chamber 10, the concentration sensor 44 for measuring the oxygen and carbon dioxide concentration in the high-pressure oxygen chamber 10, and the concentration of oxygen supplied through the oxygen supply pipe 14 It may be configured to include an oxygen concentration measuring unit 45 to measure.

The controller 33 controls the pressure regulating valve 24 and the discharge valve 26 based on the value measured by the measuring unit 40 to adjust the pressure in the high pressure oxygen chamber 10, as will be described later. , By controlling the control valve 27 and the oxygen control valve 25 to adjust the oxygen concentration of the gas supplied through the mask, by controlling the cooling device 60 so that the temperature in the chamber 10 is within the set temperature range. The control unit 70 may control the CO 2 concentration and humidity in the chamber 10 to be within a set range.

In addition, the measured value measured by the measuring unit 40 through the communication module 34 is transmitted to the receiving unit 111 of the management platform 110. The setting unit 113 of the management platform 110 sets an optimum control range and transmits a control signal to the control unit 33. That is, the setting unit 113 controls by setting the optimum control range of the pressure in the chamber 10, oxygen treatment time, oxygen supply cycle, temperature, humidity, oxygen concentration supplied, carbon dioxide in the chamber 10, oxygen concentration The signal is transmitted to the control unit 33, the control unit 33 is based on the control signal pressure control valve 24, discharge valve 26, oxygen control valve 25, control valve 27, regulator ( 70), the cooling device 60 and the like.

8 is a block diagram of the biometric information measuring unit 50 according to an embodiment of the present invention. In addition, the platform-based mobile remote management hyperbaric oxygen treatment system 100 according to an embodiment of the present invention is configured to include a biometric information measuring unit 50 for measuring the biometric information of the patient during oxygen therapy.

The biometric information measuring unit 50 measures the arterial blood oxygen saturation of the patient, the respiratory waveform, pulse, blood pressure, electrocardiogram of the patient, and the receiving unit 111 of the management platform measures the value measured by the biometric information measuring unit 50. Will be received. As shown in FIG. 6, the management platform 110 displays the value measured by the measurement unit 40 and the biometric information measured by the biometric information measuring unit 50 through a monitoring unit 112 configured as a display unit. It can be configured to be checked and monitored.

The biometric information measuring unit 50 is provided on one side of the discharge end of the mask to measure the breathing waveform of the patient in real time, the SpO2 sensor 51 for measuring the arterial blood oxygen saturation of the patient in real time, and the patient The blood pressure, pulse, electrocardiogram of the ECG sensor 53 for measuring in real time, and may include a thermometer for measuring the body temperature of the patient.

The biometric information measured by the biometric information measuring unit 50 is monitored in real time by the monitoring unit 112 of the management platform 110, and monitors the real-time image and biometric information received through a camera installed in the chamber 10 When an emergency occurs, such as a sudden change in the biometric information, it is configured to be able to broadcast through a guide unit or the like installed in the chamber 10 or directly to the patient through a wireless communication module.

In addition, the management platform 110, as shown in Figure 6, the biological information measured by the biometric information measuring unit 50 during treatment, the CO concentration of the patient measured before and after the treatment, arterial blood oxygen saturation, the mitoconcrete of the patient It can be configured to include the analysis means 114 for analyzing the oxidative stress, cell signal transmission changes to form diagnostic data. 9 illustrates a schematic diagram of biometric information management according to an embodiment of the present invention.

As shown in Figure 9, before and after the treatment, that is, before measuring the oxygen concentration, arterial oxygen saturation, electrocardiogram, blood pressure of the patient before the hyperbaric oxygen treatment, and measured the CO concentration, arterial oxygen saturation, electrocardiogram, blood pressure of the patient after hyperbaric oxygen treatment By analyzing the change state of the bio-information when the hyperbaric oxygen treatment in the set control range, the diagnostic data is formed and stored in the database 115.

In addition, it is possible to form a diagnostic data by analyzing the change in mitochondria of the patient before and after hyperbaric oxygen treatment according to an embodiment of the present invention. That is, the treatment mechanism is analyzed and stored in the database 115 based on the oxidative stress and signal transmission change of mitochondria due to the increase of oxygen by hyperbaric oxygen treatment. These diagnostic data are classified into DB by patient and disease type. In addition, the setting unit 113 sets the optimum control range based on the biometric information and the diagnostic data to transmit the control signal to the control unit 33.

10 shows a block diagram of a database 115 of the management platform 110 in accordance with an embodiment of the present invention. As shown in FIG. 10, the database 115 may include a biometric information DB, a diagnostic data DB, a patient DB, an optimal setting range DB, a disease DB, an admittance DB, a system information DB, an operation information DB, and the like. .

The operation information DB stores equipment specifications for the operation of the hyperbaric oxygen treatment system 100, and the system information DB includes the operation state information of the hyperbaric oxygen system 100, and the admittance DB is described later. Admittance of each patient for pressure control in chamber 10 is to be stored. The disease DB may store information on a type of disease, and the optimal setting range DB may store optimal setting range data set by the setting unit 113.

In addition, the patient DB records information on patient information, past treatment history, diagnostic data, and the like. The biometric information DB stores biometric information measured by the biometric information measuring unit 50 and biometric information measured before and after treatment for each patient. The diagnostic data DB stores the diagnostic data formed by the analyzing means 114.

The data stored in the database 115 and the data monitored by the monitoring unit 112 are configured to be connected to the management platform 110 through the set user terminal 1 to check and monitor.

11 is a cross-sectional view of the air supply pipe 13 and the connection pipe oxygen supply pipe 14 according to an embodiment of the present invention. As shown in FIG. 11, the connection pipe 15 connecting between the oxygen supply pipe 14 and the air supply pipe 13 may be configured to include a control valve 27 provided at one side of the connection pipe.

Therefore, the pressurized air is supplied into the chamber 10 through the air supply pipe 13 through the air supply pipe 13 by the compressor when the connecting pipe is closed and the pressure control valve 24 is opened in the pressurizing step so that the pressure in the chamber 10 is increased. . In this case, the controller 33 controls the pressure regulating valve 24 based on the pressure range of the control signal transmitted from the setting unit 113.

In addition, the oxygen control valve 25 is opened so that oxygen in the oxygen storage tank 22 is supplied to the mask through the oxygen supply pipe 14. At this time, the control unit 33 controls the control valve 27 and the oxygen control valve 25 so that the supplied oxygen concentration is the set oxygen concentration. That is, the oxygen concentration measuring unit 45 provided at one side of the oxygen supply pipe 14 measures the oxygen concentration of the gas supplied in real time, and the amount of air supplied by the control valve 27 and the oxygen control valve 25. By adjusting the amount of oxygen supplied by the control to control the gas to the oxygen concentration set to the patient.

In addition, the setting unit 113 sets the hyperbaric oxygen treatment period and the oxygen supply period, and when the oxygen brake time comes, the control unit 33 controls to close the oxygen control valve 25 and open the control valve 27. The air is drawn in through the mask. When the oxygen brake time ends, the oxygen control valve 25 is opened again, and the control valve 27 is adjusted to supply a gas having a set oxygen concentration through the mask.

In addition, as shown in Figure 11, one side of the air supply pipe 13 is provided with a cooling device 60 may be configured to cool the air supplied. The controller 33 controls the cooling device 60 to maintain the temperature in the chamber 10 in a set range based on the value measured by the temperature sensor 42.

12 shows a cross-sectional view of a cooling device 60 according to an embodiment of the present invention. As shown in Figure 12 it can be seen that the cooling device 60 according to an embodiment of the present invention can be configured in the form of a fin-micro heat exchanger. Air is introduced through the inlet end 61 of the cooling device 60 and discharged heat to the refrigerant flowing in the cooling tube 63 to be cooled and then introduced into the air supply end 13 through the discharge end 62. do. In addition, in order to maximize the heat exchange area between the cooling tube 63 and the air, the cooling tube 63 has a zigzag shape, and a plurality of cooling fins 64 may be installed on the outer surface of the cooling tube 63.

In addition, a regulator 70 for controlling carbon dioxide concentration and humidity may be installed in the high-pressure oxygen chamber 10 according to the embodiment of the present invention.

13 shows a perspective view of a regulator 70 according to an embodiment of the invention. As shown in FIG. 13, the controller 70 has a cylindrical housing 71 having an inlet on one side and an outlet on the other side, a suction fan 74 that sucks air into the interior through the inlet 72, and is sucked in. It can be seen that the present invention comprises a CO2 absorbent 75 absorbing carbon dioxide in the gas, a water absorbent 76 absorbing moisture, a dust absorbent filtering the dust, and a filtration filter 77.

Therefore, the controller 33 controls the driving of the suction fan 74 based on the values measured by the humidity sensor 43 and the concentration sensor 44 to maintain the carbon dioxide, oxygen concentration, and humidity in the chamber 10 in the set range. Be sure to

In addition, in the embodiment of the present invention, one side of the air supply pipe 13 is provided with a silencer may be configured to reduce the noise generated in the compressor (31). 14A illustrates a cross-sectional view of a silencer in accordance with an embodiment of the present invention. 14B is an exploded perspective view of the silencer according to the embodiment of the present invention.

As shown in Figure 14a and 14b, the inlet cap 82 is installed on one side of the silencer housing 81, the outlet cap 83 is installed on the other side is configured to be connected to the air supply pipe 13, the housing The inside of the porous packing material is provided to be configured to absorb noise. It can be seen that this porous packing material may be composed of a porous pipe 84 of high density polyethylene (HPPE) component, as shown in FIGS. 14A and 14B. In addition, one end is coupled to the inlet cap 82 to fix the porous pipe 84 and the other end includes a plurality of support rods 85 fastened to the outlet cap 83.

And in the embodiment of the present invention is configured to adjust the pressure in the chamber 10 while preventing the patient trauma. 15 shows a conceptual diagram of a probe 90 according to an embodiment of the present invention mounted on the ear of a patient. And Figure 16 shows a flow chart of a pressure regulating method according to an embodiment of the present invention.

As shown in FIG. 15, the probe 90 is mounted in the ear of a patient in the form of an earphone, and provides a speaker 91 for directing and outputting sound of a predetermined frequency band to the patient's eardrum, and the reflected wave reflected from the patient's eardrum. It can be seen that it can be configured to include a microphone 92 for receiving. The measurement unit 93 measures the admittance in the eardrum of the patient based on the magnitude of the output sound and the magnitude of the component corresponding to the sound among the reflected waves.

And the receiving unit 111 of the management platform 110 receives the admittance measured by the measuring unit 93, the setting unit 113 determines the pressure pressure in the chamber 10 based on the admittance to control the control signal ( 33). In addition, the controller 33 controls the pressure regulating valve 24 to supply air into the chamber 10 so as to be a set pressure.

In addition, the measuring unit 93 measures the admittance of each of the plurality of patients, and the setting unit 113 continues and continues to pressurize when the patient reaches the pressure equilibrium based on the patient having the minimum admittance during pressurization. When the pressure equilibrium state is not reached, the pressurization is stopped for a certain time, and when the pressure equilibrium state is not reached even for a certain time, the control signal is transmitted to reduce the pressure.

That is, the setting unit 113 first sets the target pressure value in the chamber 10 and sets the primary pressurization pressure based on the maximum admittance value of each patient. While increasing the pressure in the chamber 10 at the set pressure, the measuring unit 93 continuously measures the admittance, while the patient's admittance is decreased, and if there is a patient whose admittance is below the set minimum value, the pressurization is performed. If the admittance recovers above the minimum, the pressurization will continue. In addition, when the lower than the minimum value is maintained for a certain time, the discharge valve 26 is opened to depressurize.

After the pressurization is completed to the primary pressurization pressure, when the patient's admittance reaches the maximum value (pressure equilibrium state), the pressurization proceeds to the secondary pressurization pressure. The secondary pressurization process is also performed in the same manner as the aforementioned primary pressurization process and is continued until the target pressure value is reached.

When the target pressure is reached and the hyperbaric oxygen treatment is in progress, the patient's admittance is below the set minimum value, and if the state below the minimum value is maintained for a certain period of time, the pressure is reduced to induce a pressure equilibrium state and then pressurized again. . After the decompression proceeds, if the minimum level is maintained for a certain period of time after the announcement, the patient will stop the hyperbaric oxygen treatment.

In addition, the above-described apparatus and method may not be limitedly applied to the configuration and method of the above-described embodiments, the embodiments may be a combination of all or part of each embodiment selectively so that various modifications may be made It may be configured.

1: User terminal
10: high pressure oxygen chamber
11: Door
12: Chair
13: air supply pipe
14: oxygen supply pipe
20: supply room
21: air storage tank
22: oxygen storage tank
23: firefighting tank
24: pressure regulating valve
25: oxygen control valve
26: discharge valve
27: control valve
30: Machine room
31: Compressor
32: generator
33: control unit
34: communication module
40: measuring unit
41: pressure gauge
42: temperature sensor
43: humidity sensor
44: concentration sensor
45: oxygen concentration measuring unit
50: biological information measuring unit
51: SpO2 sensor
52: breathing sensor
53: ECG sensor
60: cooling device
61: Inflow end
62: discharge team
63: cooling tube
64: cooling fin
70: Regulator
71: housing
72: inlet
73: outlet
74: suction fan
75: CO2 absorbent
76: moisture absorbent
77: filtration filter
80: silencer
81: silencer housing
82: inflow cap
83: exit cap
84: porous pipe
85: support rod
90: probe
91: Speaker
92: Mike
93: measuring unit
100: Platform-based mobile remote management hyperbaric oxygen treatment system
110: management platform
111: receiver
112: monitoring unit
113: setting part
114: means of analysis
115: database

Claims (11)

In the hyperbaric oxygen treatment system,
A high pressure oxygen chamber having an interior pressurized by high pressure air, oxygen supplied to the patient through a mask, an air supply stage through which air is supplied, an exhaust stage through which internal air is discharged, and a discharge valve provided at one side of the exhaust stage;
A supply chamber in which an air storage tank and an oxygen storage tank are installed;
An air supply pipe for supplying air in the air storage tank into the high pressure oxygen chamber, a pressure control valve for controlling the pressure in the high pressure oxygen chamber by adjusting a flow rate of the air supplied at one side of the air supply pipe, and in the oxygen storage tank An oxygen supply valve for supplying oxygen to the mask and an oxygen control valve configured to adjust a flow rate of oxygen supplied and provided at one side of the oxygen supply pipe;
A machine room connected with the air storage tank, the compressor providing a supply pressure, a generator for supplying power to the compressor, and a control unit for controlling the pressure regulating valve, the oxygen regulating valve, and the discharge valve;
A pressure gauge for measuring the pressure in the high pressure oxygen chamber, a temperature sensor for measuring the temperature in the high pressure oxygen chamber, a humidity sensor for measuring the humidity in the high pressure oxygen chamber, and an oxygen and carbon dioxide concentration in the high pressure oxygen chamber; A measuring unit having a concentration sensor; And
And a management platform having a reception unit for receiving a value measured by the measurement unit, and a setting unit for setting an optimum control range and transmitting a control signal to the control unit. Platform-based mobile remote management hyperbaric oxygen treatment system comprising: a.
The method of claim 1,
The high pressure oxygen chamber, the supply chamber and the machine room are configured in a movable container form, and a plurality of patients are accommodated in the high pressure oxygen chamber.
It includes a biometric information measuring unit for measuring the arterial blood oxygen saturation of the patient, the respiratory waveform, pulse, blood pressure, electrocardiogram of the patient, the receiving platform of the management platform characterized in that receiving the value measured by the biometric information measuring platform Management of hyperbaric oxygen treatment system.
The method of claim 2,
The management platform,
Analyze the biometric data measured by the biometric information measuring unit during treatment, the CO concentration, arterial blood oxygen saturation, and oxidative stress and cellular signal change of mitochondria of patients measured before and after treatment to form and store diagnostic data. Way; And
The platform-based mobile remote management hyperbaric oxygen treatment system further comprises; database for classifying the measured value and the diagnostic data by patient, disease type by DB.
The method of claim 3, wherein
It includes a connecting pipe for connecting between the oxygen supply pipe and the air supply pipe, and a control valve provided on one side of the connecting pipe,
The setting unit sets the optimum control range of treatment time, oxygen supply cycle, oxygen concentration, pressure, temperature and humidity based on the diagnostic data, and transmits a control signal to the control unit based on platform. Oxygen therapy system.
The method of claim 4, wherein
A speaker for directing and outputting sound of a predetermined frequency band to the eardrum of the patient, a microphone for receiving the reflected wave reflected from the eardrum of the patient, the magnitude of the output sound and the magnitude of a component corresponding to the sound among the reflected wave A measurement unit for measuring admittance in the tympanic membrane of the patient,
The receiving unit of the management platform receives the admittance measured by the measuring unit, the setting unit determines the pressure pressure in the chamber based on the admittance, and transmits a control signal to the control unit, platform-based mobile remote management Hyperbaric oxygen treatment system.
The method of claim 5,
The measuring unit measures the admittance of each of the plurality of patients, and the setting unit maintains the pressurization when the patient reaches the pressure equilibrium state based on the patient having the minimum admittance during pressurization, and does not reach the pressure equilibrium state. In the case of stopping the pressurization for a certain time, the platform-based mobile remote management hyperbaric oxygen treatment system, characterized in that for transmitting a control signal to depressurize if the pressure equilibrium is not reached even during the predetermined time.
The method of claim 4, wherein
The control unit controls the control valve to supply oxygen to the set oxygen concentration, the platform-based mobile remote management hyperbaric oxygen treatment system, characterized in that for controlling the oxygen control valve to close and open the control valve during the oxygen brake time. .
The method of claim 4, wherein
One side of the air supply pipe, a platform-based mobile remote management hyperbaric oxygen treatment system, characterized in that the silencer and a silencer having a porous packing material located in the noise housing to reduce the noise of the compressor.
The method of claim 4, wherein
And a cooling device provided at one side of the air supply pipe to cool the supplied air, and the controller controls the cooling device to maintain the temperature in the chamber within a set range. system.
The method of claim 1,
Is provided on one side of the chamber and provided with at least one of a suction fan for sucking air into the interior through the inlet, a CO2 absorbent for absorbing carbon dioxide in the sucked gas, a moisture absorbent for absorbing moisture, and a dust filtration filter It further comprises a regulator;
The control unit is a platform-based mobile remote management hyperbaric oxygen treatment system, characterized in that for controlling the controller based on the values measured by the concentration sensor and the humidity sensor so that the carbon dioxide, oxygen concentration, humidity in the chamber is maintained within a set range. .
The method of claim 6,
A platform-based mobile remote management hyperbaric oxygen treatment system, characterized in that for monitoring the value measured by the measuring unit, the measured value measured by the biometric information measuring unit, the diagnostic data by accessing the management platform through a user terminal. .

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