RU45924U1 - ARTIFICIAL LUNG VENTILATION DEVICE - Google Patents

Abstract

The utility model relates to medicine, namely to the design of devices designed for artificial lung ventilation, as well as for inhalation with therapeutic gas mixtures and anesthesia. The apparatus contains a power supply unit including a gas cylinder (1) and an oxygen cylinder (2), and a breathing circuit consisting of a supply device (3) of a respiratory gas mixture to a patient, a supply pipe (4) connected to a supply device, an inspiration valve (5 ) installed in front of the device in the inlet pipe, a breathing bag (6) connected to the inlet pipe in front of the inspiratory valve, the outlet pipe (7) connected to the device, the exhalation valve (8) installed in the discharge pipe, a two-way faucet (9) installed at the end of the discharge pipe, an absorber (10) of water vapor and carbon dioxide included in the exhaust pipe in front of the two-way valve, and an exhaled gas mixture return pipe (11) connected at one end to the two-way valve and the other - to the inlet pipe in front of the breathing bag. The power supply unit is also equipped with a mixing chamber (12) connected by appropriate pipelines to an oxygen cylinder (2) and a gas cylinder, and a dosimeter (13) installed in the pipeline between the gas cylinder and the mixing chamber. The breathing circuit is additionally equipped with a gas analyzer (14) and a temperature measurement sensor (15) electrically connected to the gas analyzer, an oxygen volume fraction measurement sensor (16) installed on the inlet pipe in front of the inspiratory valve, and a carbon dioxide volume fraction measurement sensor mounted on the outlet pipe behind absorber. The proposed design of the apparatus allows to improve operational characteristics.

Description

The utility model relates to medicine, namely to the design of devices designed for artificial lung ventilation, as well as for inhalation with therapeutic gas mixtures and anesthesia, for example, using medical xenon as an anesthetic. The proposed device can be used in medical pressure chambers, in the field, during rescue operations and on board evacuation vehicles when providing emergency medical care to people with impaired breathing, as well as for the complex treatment of acute and chronic lung diseases of various etiologies and cardiovascular diseases.

Known artificial lung ventilation apparatus containing a power supply and a breathing circuit (RU 2197999 C1, 02/10/2001, IPC 7 - A 61 M 16/01).

An artificial lung ventilation apparatus (prototype) is also known, comprising a power supply unit including a gas cylinder with a reducer and an oxygen cylinder with a reducer and a metering valve, and a breathing circuit consisting of a breathing gas mixture supply device to a patient, a supply pipe connected to a supply device, an inspiratory valve installed in front of the device on the inlet pipe, a breathing bag attached to the inlet pipe in front of the inspiratory valve, the outlet pipe, etc. connected to the device, the exhalation valve installed behind the device on the exhaust pipe, regulating two-way valve installed on the end of the exhaust pipe, at least one absorber of water vapor and carbon dioxide included in the exhaust pipe in front of the two-way valve, and the exhaust gas return pipe, connected at one end to a two-way

to the crane, and to the other to the supply pipe in front of the breathing bag (RU 2183476 C2, 06.20.2002, IPC 7 - A 61 M 16/01, 16/10).

However, the known artificial lung ventilation apparatus does not have high operational characteristics, since its design lacks a mixing chamber, a dosimeter that provides precise control of the therapeutic gas mixture flow rate and determination of its amount during the treatment session, and a gas analyzer with corresponding sensors. In addition, the artificial lung ventilation apparatus can only be used in stationary conditions, since it has bulky equipment.

The objective of the utility model was to develop the design of a portable ventilator with high performance, providing high-quality preparation and monitoring of the parameters of the inhaled gas mixture, its regulation and flow measurement. In addition, when using expensive xenon in a therapeutic respiratory gas mixture, its adsorption from the exhaled mixture.

The specified technical result (improved performance) is achieved by the fact that in the artificial lung ventilation apparatus comprising a power supply unit including a gas cylinder with a reducer and an oxygen cylinder with a reducer and a metering valve, and a breathing circuit consisting of a breathing gas mixture supply device to the patient, the inlet pipe connected to the inlet device, the inspiratory valve installed in front of the device in the inlet pipe, a breathing bag attached to odvodyaschemu conduit to the inhalation valve, the discharge pipe attached to the device, the exhalation valve mounted on the device for the discharge pipe, the two-way regulating valves mounted to the end of the discharge pipe, at least one absorber of water vapor and carbon dioxide included in the

the outlet pipe in front of the two-way valve, and the return line of the exhaled gas mixture connected at one end to the two-way valve, and the other to the inlet pipe in front of the breathing bag, according to the utility model, the power supply unit is equipped with a mixing chamber connected to the oxygen pipe and the gas cylinder by corresponding pipelines, and a dosimeter installed in the pipeline between the gas cylinder and the mixing chamber. The breathing circuit is equipped with a gas analyzer and at least one temperature measuring sensor electrically connected to the gas analyzer, at least one oxygen volume fraction measuring sensor installed in the inlet pipe in front of the inspiratory valve, and at least one carbon dioxide volume fraction measuring sensor mounted on the outlet pipeline behind the absorber.

In addition, the supply device can be made in the form of a breathing mask.

It is recommended that the breathing mask be equipped with an additional breathing bag.

Along with this, the inlet device can be made in the form of a breathing cap.

It is advisable that the supply device was equipped with an inhaler.

It is also recommended that the inhaler be equipped with an ultrasonic generator.

It is envisioned that the breathing circuit may be provided with a flow inducer included in the supply line behind the inspiratory valve.

In addition, the breathing circuit can be equipped with a heater included in the supply pipe between the air bag attached to it and the installation site of the temperature sensor and the oxygen volume fraction measurement sensor.

It is also envisaged that the connecting pipes can be made in the form of flexible hoses.

It is advisable that the gas analyzer be equipped with an electronic control unit and process the electrical signals from the respective sensors, a digital oxygen concentration indicator, a digital carbon dioxide concentration indicator in the gas mixture and a digital temperature indicator.

It is also advisable that the dosimeter be equipped with a digital indicator of the flow rate of the treatment gas mixture and a digital indicator of the total amount of the treatment gas mixture during the session.

It is envisaged that in the transported position, the breathing circuit with connecting pipelines can be placed in a suitcase with a working volume formed by a housing equipped with a handle and supporting elements, while the housing is detachable and consists of two half-bodies forming a bottom and a cover, hingedly connected to each other in lower part with the possibility of their disclosure.

Along with this, it is provided that in the transported position the power supply with connecting pipelines can be placed in an additional suitcase with a working volume formed by a housing equipped with a handle and supporting elements, while the housing is detachable and consists of two half-bodies forming a bottom and a cover, pivotally connected to each other in the lower part with the possibility of their disclosure.

In addition, it is advisable that in the transported position the breathing circuit and the power supply with connecting pipelines be placed in a suitcase with a working volume formed by a housing equipped with a handle and supporting elements, while the housing is detachable and consists of two half-bodies forming a bottom and a cover, pivotally connected to each other in the lower part with the possibility of their disclosure.

For disposal of expensive xenon, it is recommended that the apparatus be equipped with a xenon adsorber, the gas mixture inlet of which is connected to a two-way valve, and the outlet is connected to the atmosphere.

In addition, in order to reduce losses of xenon into the environment, the apparatus can be equipped with an xenon slip sensor electrically connected to the gas analyzer, which is installed at the outlet of the gas mixture from the adsorber to the atmosphere.

It is envisaged that the breathing circuit may be equipped with at least one xenon volume fraction sensor in the gas mixture mounted on the inlet pipe in front of the inspiratory valve.

The drawing shows a schematic diagram of an apparatus for artificial ventilation of the lungs.

The ventilator contains a power supply and a breathing circuit. The power supply unit includes a gas cylinder (1) with a reducer, an oxygen cylinder (2) with a reducer and a metering valve. Depending on the treatment procedure, the gas cylinder (1) can be filled with various gases and therapeutic gas mixtures. For example, for artificial ventilation of the lungs, the gas cylinder is filled with xenon-gel-oxygen or gel-oxygen therapeutic gas mixture. To conduct an anesthesia session (anesthesia), the gas cylinder may be filled with medical xenon. The respiratory circuit consists of an inlet device (3) of the respiratory gas mixture to the patient, an inlet pipe (4) connected to the device (3), an inspiration valve (5) installed in front of the device in the inlet pipe, a breathing bag (6) connected to the inlet the pipeline in front of the inspiratory valve, the discharge pipe (7) connected to the device, the exhalation valve (8) installed behind the device on the discharge pipe, regulating a two-way valve (9) installed on the end of the discharge pipe, oglotitelya (10) vapor

water and carbon dioxide included in the outlet pipe (7) in front of the two-way valve (9), and the return pipe (11) of the exhaled gas mixture connected at one end to the two-way valve (9), and the other to the inlet pipe (4) before the breathing bag (6). The power supply unit is also equipped with a mixing chamber (12) connected by appropriate pipelines to an oxygen cylinder (2) and a gas cylinder (1), and a dosimeter (13) installed in the pipeline between the gas cylinder and the mixing chamber. The breathing circuit is additionally equipped with a gas analyzer (14) and a temperature measurement sensor (15), a sensor for measuring the volume fraction of oxygen (16) in the inhaled gas mixture and a sensor for measuring the volume fraction of carbon dioxide (17) in the patient’s exhaled gas mixture that is electrically connected to the gas analyzer. A temperature measurement sensor and an oxygen volume fraction measurement sensor are installed on the inlet pipe (4) in front of the inspiratory valve (5), and a carbon dioxide volume measurement sensor is installed on the exhaust pipe (7) behind the absorber (10) of water vapor and carbon dioxide. The supply device (3) of the respiratory gas mixture to the patient can be made in the form of a breathing mask. It is recommended that the breathing mask be equipped with an additional breathing bag. Along with this, the inlet device can be made in the form of a breathing cap. For inhalation, it is advisable that the supply device was equipped with an inhaler. It is also recommended that the inhaler be equipped with an ultrasonic generator. The breathing circuit may be provided with a flow inducer included in the inlet pipe (4) behind the inspiratory valve (5). In addition, the breathing circuit can be equipped with a heater (18) of the inhaled gas mixture included in the supply pipe (4) between the connection of the breathing bag (6) to it and the installation site of the temperature sensor (15) and the oxygen volume fraction measurement sensor (16). It is also envisaged that the connecting piping

can be made in the form of flexible hoses. The gas analyzer can be equipped with an electronic control unit for processing electrical signals from the corresponding sensors, a digital oxygen concentration indicator, a digital indicator of carbon dioxide concentration in the gas mixture and a digital temperature indicator, and a dosimeter - a digital indicator of the therapeutic gas mixture flow rate and a digital indicator of the total therapeutic amount gas mixture during the session.

It is envisaged that in the transported position the breathing circuit with connecting pipelines can be placed in a suitcase with a working volume formed by a body equipped with a handle and supporting elements. At the same time, the case of the suitcase is detachable and consists of two half-shells forming a bottom and a cover, pivotally connected to each other in the lower part with the possibility of their opening. The power supply with connecting piping can be placed in an additional suitcase of the same design. Along with this, in the transported position, both the breathing circuit and the power supply can be placed in one suitcase.

To collect expensive xenon and its further purification from gas impurities, it is recommended that the apparatus be equipped with a xenon adsorber (19), the gas mixture inlet connected to a two-way valve (9), and the outlet communicates with the atmosphere. In order to reduce xenon losses to the environment, the apparatus can be equipped with a xenon slip sensor (20), which is electrically connected to the gas analyzer at the outlet of the gas mixture from the adsorber to the atmosphere (14). In addition, it is provided that the breathing circuit can be equipped with a sensor for measuring the volume fraction of xenon (21) in the gas mixture mounted on the inlet pipe in front of the inspiration valve (5).

The apparatus of artificial ventilation works as follows.

A therapeutic respiratory gas mixture, for example, consisting of 10% medical xenon, 50% medical oxygen and 40% helium, is supplied under pressure from a cylinder (1) through a pressure reducer to the metering valve of the dosimeter (13), with which the flow rate of the respiratory mixture is controlled range. From the dosimeter, the gas mixture passes through the mixing chamber (12) and the inspiration valve (5) to the inlet device (to the patient's breathing mask). If necessary, the necessary amount of oxygen coming from the oxygen cylinder (2) through the gearbox and control valve into the mixing chamber (12) is added to the initial respiratory gas mixture. The gas mixture exhaled by the patient through the exhalation valve (8) through the discharge pipe (7) enters the absorber (10) of water vapor and carbon dioxide and through a two-way valve (9) is supplied to the adsorber (19) to completely absorb xenon. Part of the gas mixture exhaled by the patient can be recycled through a two-way valve (9) through the return pipe (11) to the breathing circuit. The xenon slip sensor (20), electrically connected to the gas analyzer (14), monitors the xenon saturation of the sorbent with which the internal cavity of the adsorber is filled (19). When a xenon “leak” is registered by a gas analyzer, the adsorber is switched off and replaced with another one with a regenerated sorbent. The disconnected adsorber is sealed and sent to extract xenon from the sorbent, followed by purification to a predetermined purity for reuse.

In the case of using the proposed apparatus for anesthesia using xenon as an anesthetic, gaseous medical xenon is supplied under pressure from a gas cylinder (1) to the metering valve of the dosimeter (13), by which the xenon flow rate is controlled in a predetermined range (for example, in the range from 0.01 to 0.2 l / min). Then xenon is sent to the measuring device of the dosimeter. An electronic unit for processing electrical signals from a measuring device sends data to a digital indicator

xenon consumption and a digital indicator of the total xenon during the operation. From the dosimeter (13), xenon is fed into the mixing chamber (12) for mixing with oxygen coming from the oxygen cylinder (2) in a predetermined ratio and through the supply pipe (4) the resulting binary narcotic drug mixture enters the breathing circuit to the supply device (mask (3) ) patient) for anesthesia session. The sensors (15, 16, 17 and 21) of the gas analyzer (14) continuously and automatically measure respectively the temperature of the inhaled gas mixture, the volume fraction of oxygen (with the output of the electrical signal to the digital temperature indicator and the digital indicator of oxygen concentration), the volume fraction of carbon dioxide in the exhaled gas mixture (with the output of an electrical signal to a digital indicator of the concentration of carbon dioxide) and the volume fraction of xenon (with the output of an electrical signal to a digital indicator of the composition of xenon) in a gas narcotic mixture, according stepping towards the patient.

The high performance characteristics of the proposed portable ventilator are due to the composition of the equipment, the connections of the equipment elements and its placement in a portable case (suitcase).

Claims (17)

1. An artificial lung ventilation apparatus comprising a power supply unit including a gas cylinder with a reducer and an oxygen cylinder with a reducer and a metering valve, and a breathing circuit consisting of a breathing gas mixture supply device to a patient, a supply pipe connected to a supply device, an inspiration valve, installed in front of the device on the inlet pipe, a breathing bag attached to the inlet pipe in front of the inspiratory valve, the outlet pipe connected to the inlet to an exhaust device, an exhalation valve installed behind the said device on the exhaust pipe, a control two-way valve installed on the end of the exhaust pipe, at least one absorber of water vapor and carbon dioxide included in the exhaust pipe in front of the two-way valve, and the exhaust gas return pipe connected at one end to a two-way tap and at the other to a supply pipe in front of the breathing bag, characterized in that the power supply is equipped with a mixing chamber a swarm connected by appropriate pipelines with an oxygen cylinder and a gas cylinder, and a dosimeter installed in the pipeline between the gas cylinder and the mixing chamber, and the breathing circuit is equipped with a gas analyzer and at least one temperature sensor electrically connected to the gas analyzer, at least one measurement sensor volume fraction of oxygen installed on the inlet pipe in front of the inspiratory valve, and at least one sensor for measuring the volume fraction of carbon dioxide, tanovlenii on the discharge pipe for the sink. 2. The apparatus according to claim 1, characterized in that the supply device is made in the form of a breathing mask. 3. The apparatus according to claim 2, characterized in that the breathing mask is equipped with an additional breathing bag. 4. The apparatus according to claim 1, characterized in that the supply device is made in the form of a breathing cap. 5. The apparatus according to claim 1, characterized in that the supply device is equipped with an inhaler. 6. The apparatus according to claim 5, characterized in that the inhaler is equipped with an ultrasonic generator. 7. The device according to claim 1, characterized in that the respiratory circuit is equipped with a flow inducer included in the supply pipe behind the inspiratory valve. 8. The apparatus according to claim 1, characterized in that the breathing circuit is equipped with a heater included in the supply pipe between the air bag attached to it and the installation site of the temperature sensor and the oxygen volume fraction measurement sensor. 9. The apparatus according to claim 1, characterized in that the connecting pipelines are made in the form of flexible hoses. 10. The apparatus according to claim 1, characterized in that the gas analyzer is equipped with an electronic control unit and the processing of electrical signals from the respective sensors, a digital oxygen concentration indicator, a digital carbon dioxide concentration indicator in the gas mixture and a digital temperature indicator. 11. The device according to claim 1, characterized in that the dosimeter is equipped with a digital indicator of the flow rate of the treatment gas mixture and a digital indicator of the total amount of the treatment gas mixture during the session. 12. The apparatus according to claim 10, characterized in that in the transported position the breathing circuit with connecting piping is placed in a suitcase with a displacement formed by a housing equipped with a handle and supporting elements, while the housing is detachable and consists of two half-bodies forming a bottom and a cover pivotally connected to each other in the lower part with the possibility of their disclosure. 13. The apparatus according to claim 11, characterized in that in the transported position the power supply unit with connecting pipelines is placed in an additional suitcase with a working volume formed by a housing provided with a handle and supporting elements, while the housing is detachable and consists of two half-shells forming a bottom and a cover pivotally connected to each other in the lower part with the possibility of their disclosure. 14. The apparatus according to claims 1 or 10, or 11, characterized in that in the transported position the breathing circuit and the power supply with connecting piping are placed in a suitcase with a working volume formed by a housing equipped with a handle and supporting elements, while the housing is detachable and consists of two half-shells forming a bottom and a cover, pivotally connected to each other in the lower part with the possibility of their disclosure. 15. The apparatus according to claim 1, characterized in that it is equipped with a xenon adsorber, the gas mixture inlet of which is connected to a two-way valve, and the outlet communicates with the atmosphere. 16. The apparatus according to 14, characterized in that it is equipped with an xenon leakage sensor electrically connected to the gas analyzer installed at the outlet of the gas mixture from the adsorber to the atmosphere. 17. The apparatus according to claim 1, characterized in that the respiratory circuit is equipped with at least one sensor for measuring the volume fraction of xenon (21) in the gas mixture mounted on the inlet pipe in front of the inspiratory valve.