RU2201769C1 - Apparatus for assisting breathing - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has several masks with respiratory sacks, collector, two absorbers filled with adsorbing material, filter, unit for supplying gas mixture in continuous mode having inlet and discharge valves mounted on inlet tubes of each absorber unit allowing sequential and pair-wise shutting, reverse valve mounted on outlet tubes of each absorber unit, reducing throttling valve to enable communication of absorber unit outlet tubes and nozzles having receivers mounted in series in font of collector unit. Regulator unit has pipes having dosing valve for making filter- to-collector communication. Atmospheric air sampler optionally has compressed air supply source and compressor. EFFECT: prolonged service life in uninterrupted mode. 5 cl, 1 dwg

Description

 The invention relates to medical equipment, and more particularly to apparatus for producing gas mixtures - oxygen depleted air (hypoxic gas mixture), and oxygen enriched air (hyperoxic gas mixture).

 The invention can be used, for example, to obtain a gas hypoxic mixture during normobaric hypoxytherapy, carried out in order to increase the nonspecific resistance of the organism in the prevention, treatment and rehabilitation of a wide range of diseases.

Known breathing apparatus for hypoxytherapy, including a mask, channels and valves for inhalation and exhalation, a means for changing the concentration of carbon dioxide (CO ₂ ) in an inhaled mixture of gases, made in the form of a housing containing a CO ₂ absorber with a lid with an intake of atmospheric air [1]. This breathing apparatus is quite simple to manufacture and use, however, due to design features it does not meet modern requirements for ensuring the concentration of oxygen in the inhaled gas mixture in all operating modes.

A device for the treatment and prevention of respiratory and circulatory organs, including a mask, breathing bag, inspiratory and expiratory pipelines and a stabilizer of the composition and temperature of the inhaled gas mixture, made in the form of a shutter with a fixing handle mounted with the possibility of longitudinal movement on a rectangular atmospheric opening - window [ 2]. This device does not provide a means for changing the concentration of oxygen (O ₂ ) in an inhaled mixture of gases, which significantly limits its applicability for medicinal purposes.

 Both well-known technical solutions [1, 2], in addition to the indicated disadvantages, are means for individual use only.

 A known apparatus for hypoxytherapy, the respiratory circuit of which consists of a mask, inspiratory and expiratory valves, absorber, filter, respiratory reservoir, air intake, valve box and filter box with antibacterial and antiviral filters [3]. A disadvantage of the known apparatus is the presence of replaceable and disposable elements in it, which does not allow using it in a continuous cycle with an indefinite number of patients.

 A device for normobaric hypoxytherapy [4] is also known, containing a compressor, a gas separation membrane apparatus, a system for monitoring the patient's condition and regulating the composition of the mixture. The mixture is supplied to the patients in the form of a mask connected to the outlet of the hypoxic pipeline through the storage tank. The device is autonomous in operation and safe to operate, but, as practice has shown, a gas distribution membrane apparatus having a set of membrane packages of polymer materials is very sensitive to the humidity of the compressor air supplied to it. With a gradual saturation with moisture, the membranes fail and require replacement, which is equivalent to the cost of replacing the entire apparatus. An individual breathing regimen is selected according to one patient, since the apparatus has one gas analyzer and one gas mixture quality control system. In the individual mode of changing the concentration of oxygen in the gas mixture, each patient should have gas analyzers. Therefore, the individual selection of breathing is complicated.

 A known apparatus for breathing, made in the form of a single channel of inhalation-exhalation formed by a mask, a breathing bag, an air intake with a regulator, an absorber with attached tubes and a removable filter with antiviral and antibacterial elements [5]. This device design provides the convenience and effectiveness of its use by individual users on an outpatient basis. The specified known device is adopted as a prototype, as the closest in technical essence and the achieved result analogue.

 The disadvantage of the prototype is the presence in it of disposable and replaceable elements, as evidenced by the presence of a removable disposable filter and the need for periodic replacement of the absorber. In addition, the device is not intended for collective use simultaneously by several patients. Thus, the known technical solution can hardly be applied in a hospital treatment or prophylactic institution with a massive flow of patients.

 The present invention is aimed at achieving a technical result, which is expressed in ensuring the possibility of continuous operation of the apparatus for almost unlimited time while maximizing the preservation of all the positive properties of the prototype.

 Ultimately, an uninterrupted supply of a respiratory gas mixture with constant parameters allows the device to be used in stationary conditions with a mass flow of patients.

 The specified positive technical result is achieved by the fact that the breathing apparatus, including a mask communicating with each other, a breathing bag, an atmospheric air intake with a regulator, a filter and an absorber, made in the form of a housing filled with adsorbent with inlet and outlet pipes, is equipped with at least one additional mask with a breathing bag, a manifold for supplying the gas mixture to the masks, an additional absorber and a continuous supply of the gas mixture. The primary and secondary absorbers are arranged in such a way that their inlet pipes are in communication with the intake of atmospheric air through a filter, and the output pipes are in communication with each other and with the collector. The continuous supply of the gas mixture is a system of inlet and exhaust valves installed on the inlet pipes of each of the absorbers with the possibility of alternating and pairwise overlapping them, a check valve installed on the output pipe of each of the absorbers, a bypass throttle for communication between the output pipes of the absorbers and nozzles with a receiver sequentially mounted in front of the collector. The atmospheric air intake is a high pressure pipeline with elements for connecting to a compressed air network, and the regulator is a pipeline with a metering valve for connecting the filter to the collector.

 Preferred is the embodiment of the apparatus, in the continuous supply of the gas mixture of which there is a pulse time relay, and each inlet and exhaust valve is made with the possibility of actuation from the control pulses of the time relay. It is also possible to equip the apparatus with a gas analyzer to control the composition of the gas mixture entering the collector and the atmospheric air intake in series connected by a compressor and a heat exchanger. In addition, the breathing apparatus may be equipped with a sound absorber installed at the outlet of each exhaust valve.

 The drawing shows a schematic diagram of a breathing apparatus.

 The breathing apparatus contains at least two masks 1 with breathing bags 2, in communication with the manifold 3 for supplying a gas mixture. The main 4 and additional 5 absorbers are made in the form of a case filled with adsorbent with inlet 6 and outlet 7 nozzles. The continuous gas mixture supply unit 8 consists of two inlet 9 and 10, two exhaust 11 and 12, two check valves 13 and 14, a bypass throttle 15, a nozzle 16 and a receiver 17. The regulator 18 is a pipeline with a metering valve 19. The device has a filter 20, connected to an intake of atmospheric air 21, which is made in the form of a pressure pipeline with shut-off and control valves 22 and means for connecting 23 to the compressed air network, and can also be equipped with a compressor 24 and a heat exchanger 25 in parallel.

 In the block 8 of continuous supply of the gas mixture, an electronic pulse time relay 26 can be installed, electrically connected to the inlet 9, 10 and exhaust 11, 12 valves, the latter equipped with noise absorbers 27. Before entering the manifold 3, a gas analyzer 28 is preferably located.

 The breathing apparatus operates as follows.

 The air intake 21 through the connection means 23 is connected to a stationary network of compressed air. A compressor 24 can also serve as a source of compressed air, which draws air directly from the atmosphere, and the shut-off and control valves 22 ensure that air does not enter the intake 21 through the connecting means 23. When the compressor is provided, the compressed air is cooled in the heat exchanger 25, and then it is cleaned filter 20. If network compressed air is used, it is subjected to pressure stabilization by means of shut-off and control valves 22. The presence of a double source of compressed air in the apparatus increases its usability and reliability under all operating conditions.

Compressed air from the filter 20, in which condensate is also separated, enters the absorber 4 through the open intake valve 9, while the exhaust valve 12 is open and the valves 10 and 11 are closed. In the absorber 4, the housing of which is filled to obtain a hypoxic gas mixture with an adsorbent of the UMS type (carbon molecular sieve), air is separated by short-cycle adsorption with nitrogen evolution and O ₂ absorption. The gas mixture through the pipe 7, the non-return valve 13, the nozzle 16 enters the receiver 17 and through the manifold 3 simultaneously to all masks 1 equipped with breathing bags 2. The number of patients is determined by the number of masks 1, but the device can function even if there are no patients in idle mode . The uniformity of the distribution of the gas mixture in the masks 1 is achieved due to the equal hydraulic resistance, adjustable due to the length of the capillary tube from the collector 3 to the mask 1.

 Duza 16, which is a calibrated hole, allows you to obtain maximum separation efficiency by maintaining optimal operating pressure in the absorber 4 and prevents the selection of low-quality gas mixture during transient conditions. The receiver 17 accumulates the gas mixture and smoothes out the pressure fluctuations in the manifold 3. At the same time, the gas mixture is supplied through the nozzle 7 of the absorber 4 and the bypass choke 15 to the case of the absorber 5 through its nozzle 7. A part of the adsorbent gas mixture obtained in the absorber 4 is purged in the absorber 5. Bypass the throttle 15 has a two-way effect and provides a certain amount of flow of the purge gas mixture. When purging, the adsorbent in the absorber 5 is regenerated (restores the ability to release nitrogen), and since the exhaust valve 12 is open, the purge gas mixture is released into the atmosphere through a noise absorber 27. The presence of a noise absorber 27 allows the apparatus to be installed directly in treatment rooms. After the regeneration process of the adsorbent in the absorber 5, the valve 12 is closed by a command from the relay 26 and the absorber 5 is filled with a production gas mixture to an excess operating pressure of 0.4 MPa. Then, at the command of the relay 26, valve 9 is simultaneously closed and valves 10 and 11 open, and according to the cycle described above, the respiratory gas mixture is produced in the absorber 5 and the adsorbent is regenerated in the absorber 4. The cycle time is approximately forty seconds and is provided by the relay operation cyclogram 26 .

Monitoring the concentration of O ₂ in the gas mixture entering the manifold 3 is provided by the gas analyzer 28 with a light or sound signal of the minimum and maximum values.

The gas mixture in the receiver 17 for the process of hypoxytherapy contains 5-6% O ₂ . Fluctuations in concentration reach ± 0.5% O ₂ . The working gas mixture for breathing patients should contain 10 ± 0.5% O ₂ . The metering valve 19 of the regulator 18 serves to dilute the gas mixture entering the manifold 3, until it reaches the required parameters. The purified atmospheric compressed air after exiting the filter 20 has almost 100% humidity and, passing through the regulator 18 and the metering valve 19, mixes in a certain proportion with the gas mixture coming from the receiver 17, increasing the humidity of the latter to 60-80% and the content of O ₂ up to 10 ± 0.5%. All parameters of gas mixtures (pressure, flow, humidity, concentration) are set at the initial start-up of the apparatus and do not require further adjustment. All patients breathe the same gas mixture with constant parameters, but according to an individual temporary regimen. The mode is determined before each procedure on the transcutaneous computer hardware-software complex Doctor-A, which is part of the treatment room.

When filling the absorber casing with 4 and 5 adsorbents on NaX and CaA zeolites, the apparatus provides the possibility of obtaining a hyperoxic gas mixture due to the release of O ₂ and absorption of nitrogen in the operating cycle. For the oxygen therapy process, the gas mixture in the receiver 17 may have an O ₂ concentration ranging from 50 ± 0.3% to 92 ± 0.3%. When diluted with atmospheric compressed air through a regulator 18, the O ₂ content decreases and its relative humidity rises. The control value of the lower and upper limits of the concentration of O _{2 is} set on the gas analyzer 28 and in emergency cases, a light or sound signal informs the medical staff about the changes.

 Thus, the breathing apparatus allows continuous production of both hypoxic and hyperoxic gas mixtures with strictly specified parameters from atmospheric air. At the same time, the device does not need current adjustment, adjustment and maintenance and provides the possibility of an individual breathing regime for several patients at the same time.

Sources of information
1. Copyright certificate of the USSR 1599026, cl. A 61 M 16/00, 1990

 2. USSR copyright certificate 1607817, cl. A 61 M 16/00, 1991

 3. USSR patent 1826918, cl. A 61 M 16/00, 1991

 4. RF patent 2019199, cl. A 61 M 16/10, A 61 Q 10/10, 1990

 5. RF patent 2040279, cl. A 61 M 16/00, 1992 - a prototype.

Claims (5)

 1. A breathing apparatus, comprising a communicating mask, a breathing bag, an atmospheric air intake with a regulator, a filter and an absorber made in the form of an adsorbent-filled housing with inlet and outlet nozzles, characterized in that it is equipped with at least one additional mask with a breathing bag, a manifold for supplying the gas mixture to the masks, an additional absorber and a continuous supply of the gas mixture, while the absorbers are installed in such a way that their inlet pipes are in communication atmospheric air through the filter, and the outputs are interconnected and with the collector, the continuous gas mixture supply unit is made in the form of inlet and exhaust valves installed on the inlet pipes of each of the absorbers with the possibility of alternating and pairwise overlapping them, a check valve installed on the outlet pipe each of the absorbers, a bypass choke for communicating the output nozzles of the absorbers with each other and nozzles with a receiver sequentially installed in front of the collector, atmospheric intake spherical air is made in the form of a pipeline of high pressure, and the regulator is in the form of a pipeline with a metering valve for communication of the filter with the collector.  2. The breathing apparatus according to claim 1, characterized in that it is equipped with a pulse time relay installed in the continuous gas mixture supply unit, and each inlet and exhaust valve is operable by the control pulses of the time relay.  3. The breathing apparatus according to claim 2, characterized in that the atmospheric air intake is equipped with a compressor and a heat exchanger connected in series.  4. The breathing apparatus according to claim 3, characterized in that it is equipped with a gas analyzer to control the composition of the gas mixture entering the manifold.  5. The breathing apparatus according to claim 4, characterized in that it is equipped with a noise absorber installed at the outlet of each exhaust valve.