RU2190431C2 - Insulating respiratory system - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has oxygen source, balloon for storing gas mixture, recirculation circuit, having respiration sack with excessive pressure discharge valve, main, discharge agitator unit, filtration cartridge for removing harmful substances, gas distributor unit and individual breathing units having semi- masks, valve boxes, tubes for in- and exhaling, absorption cartridges, bacterial filters. The respiration sack is divided into two unequal parts with partition having non-return valve. Permeable carcass is placed inside of the greater part receiving the recirculation circuit and balloon for storing gas mixture with pulmonary automate, reducer and globe valve. Removable oxygen production units as oxygen source are connected to the smaller part through a collector unit with globe valves. EFFECT: prolonged service life. 2 cl, 1 dwg

Description

 The invention relates to insulating respiratory systems of pressurized objects and can be used as a means of protecting the respiratory organs of divers in emergency compartments of a submarine and people in gas-tight sealed rooms at normal and high pressure, as well as during decompression of divers in emergency cases after descent to depths of up to 60 m .

 Known insulating respiratory system consisting of a breathing bag with an overpressure valve and a pulmonary machine, a pipeline, oxygen and gas mixture storage cylinders, an individual breathing module consisting of a half mask, valve box, inspiratory and expiratory tubes, an absorbent cartridge / Sets of insulating respiratory devices for decompression of IDA-72D1 and IDA-72D2. Technical description and operating instructions 9BO.293.029TO, 1988. /. When inhaling, the gas medium from the breathing bag through the inspiration valve enters the rescue, and when exhaling through the exhalation valve and the absorption cartridge returns to the breathing bag. In addition, the gas mixture is continuously supplied to the apparatus breathing system from the stationary system of storage cylinders, thereby ensuring the maintenance of a given oxygen composition in the breathing bag. Excess gas mixture from the breathing bag is etched by the overpressure valve into the environment.

 The disadvantages of this system are its low efficiency due to the high flow rate of the respiratory gas medium due to its continuous supply and short duration of operation - not more than 6 hours, as well as the bulkiness of the system. In addition, this system does not provide cleaning of the respiratory gas mixture from harmful metabolic substances.

 The closest analogue to the proposed system in terms of technical essence and the achieved result is an insulating respiratory system consisting of an oxygen source, a gas mixture storage tank, a recirculation loop containing an elastic breathing bag with an overpressure valve, a pipeline, a flow inducer, and a filter cartridge for removal harmful substances, gas distributor, and from individual breathing modules containing half masks, valve boxes, inspiratory and expiratory tubes, absorbing cartridges, ba ter filters / Patent RF N2045226 "self-contained breathing system", 1992, prototype /. Each rescued, using the individual breathing module, is connected to a system where carbon dioxide is absorbed and bacteria are cleaned of the gas environment. At the moment of connecting the rescued by breathing from the system, the flow rate activator is turned on and the recirculation circuit is put into operation. The partial pressure of oxygen in the system is controlled by an automatic gas analyzer, and oxygen is supplied from an oxygen storage tank.

 The disadvantage of such a system is its short duration of operation - about 14 hours.

 An object of the invention is to increase the duration of the system through the use of replaceable oxygen generators.

 This is achieved by the fact that in an insulating respiratory system consisting of an oxygen source, a gas mixture storage cylinder, a recirculation loop containing an elastic air bag with an overpressure valve, a pipeline, a flow inducer, a filter cartridge for removing harmful substances, a gas distributor, and from individual breathing modules containing half masks, valve boxes, inspiratory and expiratory tubes, absorbing cartridges, bacterial filters, according to the invention, the breathing bag is divided into two unequal part with an elastic partition with a non-return valve, and inside the greater part there is a permeable skeleton and a recirculation loop and a gas mixture storage tank with a pulmonary automaton, gearbox and shut-off valve are connected to it, and an oxygen source is connected to the smaller part through a manifold with shut-off valves, as which uses interchangeable oxygen generators. In addition, the volume of most of the respiratory sac exceeds the volume of the rigid frame by ΔV = n • V; where n is the number of individual breathing modules, V is the estimated inspiratory volume of 1 person (3-4 liters).

 The technical result that is obtained by the implementation of the invention is to increase the duration of the system.

 An insulating respiratory system is shown schematically in the drawing.

 The system consists of a breathing bag, divided into two parts: a large 1 with an overpressure valve 2 and a smaller 3 elastic partition 4 with a non-return valve 5. Inside the larger part 1 there is a permeable rigid frame 6 and a recirculation circuit consisting of pipeline 7 is connected to it flow driver 8, filter cassettes 9 for removing harmful substances, gas distributor 10, and individual breathing modules, consisting of a corrugated inspiratory tube 11, valve box 12, half mask 13, corrugated exhalation tube 14, swallow an integral cartridge 15 and a bacterial filter 16. A large part 1 of the breathing bag is connected to the storage tank of the gas mixture 17 through a pulmonary machine 18, a gearbox 19 and a shut-off valve 20. To a smaller part 3 of the breathing bag, oxygen replaceable generators 22 are connected via a manifold 21 with shut-off valves .

 The gas distributor 10 is a cermet membrane in the form of a hollow cylinder, one end of which is connected to the outlet of the filter cartridge 9.

 Permeable rigid frame 6 is a solid mesh cylindrical shape.

 Most of the 1 respiratory bag serves as a reservoir of the gaseous medium for breathing of the rescued, and its volume exceeds the volume of the rigid frame by ΔV = n • V: where n is the number of individual breathing modules, V is the estimated inspiratory volume of 1 person (3-4 liters).

 The smaller part 3 of the air sac serves as a reservoir of oxygen.

 The work of the insulating respiratory system is as follows.

 Most of the 1 air bag is filled with the gas mixture from the storage cylinder 17. Each person being saved, using the individual breathing module, is connected to the system. In this case, breathing is carried out through the half mask 13 and valve box 12. Upon exhalation, the gas mixture passes through the corrugated exhalation tube 14 into the absorption cartridge 15 with a chemical absorber, where carbon dioxide is absorbed, and then goes through the bacterial filter 16 to most of the respiratory bag 1. When inhaling, the gas mixture from the greater part 1 through the corrugated tube of the inhalation 11 enters the valve box 12 and to the rescued inspiration.

 Most of the 1 respiratory bag is filled with gas medium at normal or elevated pressure (up to 0.6 MPa) manually from the storage cylinder 17 through a pulmonary machine 18, gearbox 19 and shut-off valve 20.

 At the moment of connecting the rescued by breathing from the system, the flow rate trigger 8 is turned on and the recirculation ventilation and cleaning circuit of the respiratory gas medium is put into operation. In this case, the gas medium from the greater part 1 of the breathing bag through the pipeline 7 enters the inlet of the flow inducer 8 and then, after purification from harmful substances in the filter cassette 9, returns through the ceramic-metal gas distributor 10 to the greater part 1 of the breathing bag.

 In addition, at the moment of connecting the respected from the system to the manifold 21 with shut-off valves, replaceable oxygen generators 22 are connected. As oxygen is generated by the generators 22, the smaller part 3 of the breathing bag begins to fill up. During the breathing of the rescued, carbon dioxide is absorbed in the absorption cartridge 15 from the gas mixture and its volume in the system decreases, so that the greater part 1 of the breathing bag is crimped to the permeable frame 6, and then it starts to discharge. At this moment, from the smaller part 3 of the breathing bag through the non-return valve 5, oxygen begins to flow into the larger part 1, compensating for the vacuum. Upon exhalation, the gas mixture fills the volume of the greater part 1 of the breathing bag, which exceeds the volume of the rigid frame 6, while the nitrogen content in the gas mixture is maintained.

 After the operation of the oxygen generators 22, they are removed and replaced with new ones.

 In the case of decompression, the overpressure from the greater part 1 of the breathing bag is released through the overpressure valve 2.

 As a chemical absorber in cartridge 15, a chemical absorbent calcareous HP-I or CP-IR can be used, the mass of which in each cartridge is 1.8-2.0 kg.

 As a bacterial filter 16, a filter with a Petryanov tissue can be used.

As an inducer of consumption 8, an electric fan (27 V, 10 m ³ / h) with a DC motor of the brand DB 60-60-4.

 As a filter cartridge 9 for removing harmful substances - filter cartridge FKB-25.

 As replaceable oxygen generators 22 - briquette solid source of oxygen TIK-2M.

 A standard cylinder (V = 40 L, P = 150-200 atm) was used as a storage container for the gas mixture 17, and air was used as a gas mixture.

The volume of most of 1 respiratory bag for 10 people exceeds the volume of the rigid frame 6 by
ΔV = n • V = 10 • 3 = 30 (l),
where n = 10 modules of individual breathing;
V = 3 liters.

 At the same time, the system provides the vital activity of 10 people for 24-36 hours.

 Thus, the proposed system according to its technical parameters has high reliability and safety during operation and ensures the stay of a group of people in a gas-tight sealed room both at normal and at elevated (up to 0.6 MPa) pressure.

 The isolating respiratory system (prototype) is taken as the base object. Compared with the base object of the present invention increases the duration of the system by 1.5-2 times.

 The system as of 1997 is at the prototype stage.

Claims (2)

 1. An insulating respiratory system containing an elastic breathing bag with an overpressure valve connected to a recirculation circuit consisting of a pipeline, a flow inducer, a filter cartridge for removing harmful substances and a gas distributor, an individual breathing module consisting of a corrugated inspiration tube, valve box, half masks, corrugated exhalation tube, absorption cartridge and bactericidal filter, gas mixture storage cylinder, pulmonary machine, gearbox and shut-off valve, connected th to the breathing bag, and an oxygen source, characterized in that the oxygen source is made in the form of replaceable oxygen generators connected through a manifold with shut-off valves to a smaller part of the breathing bag, divided into two parts by an elastic partition with a valve providing oxygen from the smaller to the larger part of the breathing bag, while inside the greater part of the breathing bag, a permeable rigid frame in the form of a mesh is installed, a recirculation loop, individual modules are connected to the majority respiration and a gas-keeper.  2. An insulating respiratory system, characterized in that the volume of most of the respiratory bag exceeds the volume of the rigid frame by ΔV = n • V, where n is the number of individual breathing modules; V is the estimated inspiratory volume of 1 person.