RU2030190C1 - Respirator with chemically-fixed oxygen - Google Patents

Abstract

FIELD: means for protection of respiratory organs. SUBSTANCE: respirator comprises successively-connected face portion 1, carbon dioxide absorber 2, breathing bag 4, buffer container 5 and oxygen generator 3. The buffer container accommodates tensioning member 23 interacting with tension-type valve 25 disposed outside the breathing bag . Tension-type valve 25 communicates with the atmosphere and oxygen generator through return valve 28. The apparatus functions on the pendulum breathing principle. On starting, the breathing circuit of the apparatus contains a breathing mixture with a required concentration of oxygen; later, the delivery of oxygen into the breathing circuit from generator 3 is set by adjusting device in accordance with the oxygen demand for breathing. If the oxygen delivery and consumption become unbalanced, the surplus oxygen is discharged into the atmosphere through tension-type valve 25. The latter is opened by the tension member 23 interacting with the breathing bag. EFFECT: higher comfort of breathing achieved by maintaining oxygen concentration in breathing mixture at physiologically acceptable minimum. 1 dwg

Description

 The invention relates to respiratory protection and can be used in the manufacture of chemically bound oxygen insulating breathing apparatus.

 Known breathing apparatus, consisting of a front part, a carbon dioxide absorber, an oxygen generator, a breathing bag and a buffer tank, which smooths out the effects of fluctuations in the volume of the respiratory bag during human breathing on the operation of the controller located in it.

 The breathing bag communicates with the buffer tank through a calibrated hole. One of the walls of the buffer tank is made rigid, the regulator is made in the form of a two-position shutter mounted in the buffer tank on a rigid wall. The oxygen generator is made with the main and additional outputs located on opposite ends of the generator and communicated with the buffer capacity through two nozzles interacting with the damper.

 Thus, the design of the apparatus makes it possible to bring the volumetric rate of its supply from the generator in accordance with the actual consumption of oxygen and practically eliminate the wasteful use of oxygen.

 However, the task is not fully solved when using the known apparatus at low loads (pulmonary ventilation 10-15 l / min, minute oxygen consumption of 0.7-1.0 l). In this case, the minimum possible productivity of the oxygen generator (1.2-1.5 l / min) is 1.5-2 times higher than the actual need for it. The decrease in the oxygen productivity of the oxygen generator below the minimum level is associated with a number of technical difficulties and, first of all, with the practical impossibility of providing stable combustion of a solid oxygen source of a small (less than 20 mm in diameter) cross section with which the oxygen productivity of the latter is directly related.

 Thus, during operation of the known apparatus at light loads, there is a gradual increase in the concentration of oxygen in the respiratory circuit due to its excess in excess. Breathing a gas mixture with a high oxygen content (over 30 vol.%, And in the case of using the apparatus in question, it can gradually reach 80-95 vol.%) Is undesirable, and with prolonged exposure, which occurs during operation of the breathing apparatus at low loads, generally becomes unsafe from a medical point of view (the consumer may begin to show symptoms of oxygen intoxication). In addition, the use of the known apparatus by children, whose pulmonary ventilation is much less than that of adults, is also limited for the reasons discussed above.

 The aim of the invention is to ensure comfortable breathing in the apparatus by maintaining the concentration of oxygen in the respiratory mixture at a physiologically acceptable level.

 This is achieved by the fact that in a breathing apparatus containing a front part, a carbon dioxide absorber, a breathing bag connected to the breathing bag through a calibrated hole, a buffer tank, one of whose walls is rigid, a regulator in the form of a two-position shutter mounted in a buffer tank on a rigid wall , and an oxygen generator with the main and additional outputs located on opposite ends of the generator and communicated with the buffer capacity through two nozzles interacting with the damper, itelny oxygen generator output is further communicated with the atmosphere through a check valve installed in series and the valve tensioning action associated with the breathing bag placed in the tension member.

 Such a constructive implementation of the breathing apparatus allows limiting or even eliminating under certain conditions the intake of excess oxygen in the respiratory circuit in excess of the actual demand due to the release of excess oxygen from the chemical generator through the pipe into the surrounding atmosphere. The release is carried out when an amount of oxygen mixture is accumulated in the breathing bag, which, due to a corresponding increase in pressure inside the breathing bag, ensures that the tensioning valve opens through the tension element connected to the breathing bag.

 The drawing shows the proposed apparatus.

 The breathing apparatus consists of the front part 1, the carbon dioxide absorber 2, the oxygen generator 3, the breathing bag 4 and the buffer tank 5. The front part 1 is connected to the carbon dioxide absorber 2 by the pipe 6, and the absorber 2 is in turn connected with the breathing bag 4 by the pipe 7 The respiratory bag 4 and the buffer tank 5 are connected by a pipe 8 of a limited section. Inside the buffer tank 5 there is a control device consisting of a two-position shutter 9 and springs 10 and 11. The springs 10 and 11 provide, when compressed (stretched), the shutter 9 rotates around an axis fixed to the rigid wall 12 of the buffer tank 5, and is overlapped by plates 13 and 14 nozzles 15 and 16, respectively connected with the main 17 and additional 18 outputs of the oxygen generator 3 using nozzles 19 and 20.

 The design of the regulating device of the buffer tank 5 provides the simultaneous overlap of only one of the nozzles 15, 16, which makes it possible to continuously supply oxygen to the buffer tank 5 from the generator 3 either through the main 17 or through its additional 18 outputs.

 The breathing bag 4 is provided with an overpressure valve 21. One of the walls 22 of the breathing bag 4 is rigid. A tension element 23 is placed inside the bag 4, one of the ends of which is fixed to the non-rigid wall 24 of the breathing bag 4, and the second is connected through a seal-tight hole in the rigid wall 22 (not shown) with a tension valve 25 mounted on it. The seal may be, for example, an oil seal or a membrane type. The valve 25 has a hole 26 for oxygen release and is connected by a pipe 27 through a non-return valve 28 with a pipe 20 near the connection of the latter with a nozzle 16, for example, at point 29. Sealing the hole in the rigid wall 22 of bag 4 eliminates the possibility of gas leakage from the breathing bag 4 through this the hole in the inner cavity of the valve 25 and then through the hole 26 into the atmosphere. Bleeding gas from the breathing bag 4 is only possible through valve 21. The response pressure of valve 21 and valve 25 is selected so that the opening of valve 25 always precedes the opening of valve 21, i.e. Bleeding the excess oxygen from the oxygen generator 3 through the pipe 27 through the valve 25 should occur even before this excess enters the respiratory circuit of the device, and only if the gas pressure nevertheless increases in the breathing circuit for one reason or another. The latter, in order to avoid causing barotrauma to the consumer, is vented from the breathing circuit through valve 21 located in the breathing bag 4. For example, if valve 21 is activated at an overpressure of 50 mm water column, valve 25 must be activated at a slightly lower pressure, for example, 30 mm water. Art.

 With a correctly selected passage section of the nozzle 27 and the actuation pressure of the valve 25 in the breathing bag 4, the pressure will almost never increase to a value corresponding to the opening of the valve 21. And only in the case that is uncharacteristic for normal operation of the device, in which either blockage of the nozzle 27 may occur, either jamming of the check valve 28, or a break in the connection of the valve 25 with the tension element 23, etc., the pressure in the breathing bag 4 can increase to a critical value and cause the valve 21 to operate.

 The execution of one of the walls of the breathing bag 4 rigid (in this case, the wall 22) is necessary on the one hand to ensure the normal functioning of the tension element 23 (in this case, with increasing pressure in the bag 4, the tension element 23 must stretch and allow the valve 25 to open, and vice versa) , and on the other hand, to enable mounting on the rigid wall 22 of the valve 25 and connecting it through a sealed hole in the rigid wall 22 with the tension element 23.

 To ensure the normal operation of the device, i.e. To maintain the required composition of the gas mixture in the breathing circuit, at least the concentration of oxygen in it requires an initial filling of the breathing circuit, for example with air. If in most known insulating apparatuses when they are turned into operation, predominantly pure oxygen from the so-called starting briquettes enters the respiratory circuit, which practically from the first minutes of the apparatus operation causes a sharp increase in the oxygen concentration in the respiratory circuit, then this phenomenon must be eliminated due to initial filling of the respiratory circuit with gas with limited oxygen content. For example, this can be realized using a starting briquette that generates nitrogen along with oxygen, while the volume ratio of oxygen and nitrogen should approximately correspond to their ratio in air. Another acceptable way of initially filling the breathing bag is a well-known way of activating the work of the regenerative product used in regenerative apparatuses by means of which the consumer exhales several exhalations into the apparatus before it is included in the latter. Filling the respiratory circuit with gas with a limited oxygen content (at the level of 20-30 vol.%) Is possible in other ways.

 Subject to the above conditions, the initial filling of the respiratory circuit of the apparatus with gas of controlled composition subsequently requires only maintaining this composition at approximately the initial level. The latter is realized almost during operation of the apparatus of the proposed design.

 The operation of the proposed device under conditions of moderate, medium-heavy or heavy load (pulmonary ventilation 30-60 l / min), when the oxygen productivity of the generator 3 can be brought into line with the actual amount of oxygen consumed (how much oxygen is released, so much of it is consumed, without significant changes in the composition of the gas mixture in the respiratory circuit) is practically no different from the well-known apparatus working under these conditions.

 In the case when the oxygen consumption is insignificant (pulmonary ventilation 10-15 l / min, oxygen consumption 0.7 + 1.0 l / min) and it cannot be brought into line with the oxygen production of the oxygen generator (the latter exceeds the consumption) part of the generated oxygen must be vented into the atmosphere, thereby eliminating its ingress into the respiratory circuit. Only excess of the generated oxygen is subject to etching. Another part of it, corresponding to the consumption for breathing, must still enter the respiratory circuit in the usual way characteristic of the known apparatus.

 In the initial state, the structural elements of the proposed apparatus, providing the possibility of bleeding part of the generated oxygen into the atmosphere, occupy a position in which the valves 25 and the check valve 28 are closed, the tension element 23 is compressed.

 The condition for the start of bleeding oxygen from the generator 3 is such an increase in pressure in the breathing bag 4, which is typical for the unbalancing of the process "oxygen supply -> oxygen consumption" in the direction of exceeding the supply rate with the corresponding gradual accumulation of unspent excess oxygen in the breathing circuit (breathing bag 4) . The increase in pressure in the bag 4 leads to a change in the position of the tension element 23 (it stretches to a certain limit, after which it has a unidirectional effect on the tension valve 25 and opens it).

 After opening the valve 25, the pressure of the generated oxygen opens the check valve 28 and the oxygen entering through the additional output 18 of the generator 3 through the nozzle 20 towards the nozzle 16, at the point 29 has the opportunity to continue to flow or, as usual, through the nozzle 16 into the buffer tank 5 and then into the respiratory the circuit of the apparatus, or through a non-return valve 28 through a pipe 27 to the inlet of the tension-acting valve 25 and pushed out of it through the outlet 26 into the atmosphere. The preferred direction of oxygen movement from point 29 is determined by the mutual ratio of the resistances of the sections along which oxygen can move, i.e. on the one side of the respiratory circuit, on the other side of the elements of the oxygen bleeding line (non-return valve 28 - pipe 27 - tension valve 25). Since when the valve 25 is open, the resistance of the valve 28 and the pipe 27 due to their design and appropriate selection can be less than the resistance of the nozzle 16, the oxygen from point 29 will predominantly enter the atmosphere through the bleed line, until the valve 25 closes.

 The purpose of the valve 28 is to prevent the ingress of contaminated air from the surrounding atmosphere into the respiratory circuit of the device in case of breakage, jamming, etc. disturbances in the operation of the valve 25 when the latter is in the open state, providing the possibility of communication of the respiratory circuit of the device with the external environment. Since the check valve 28 allows gas to pass in only one direction (from the apparatus to the outside, but not vice versa), its presence in the design of the apparatus proposed eliminates the possibility of toxic substances entering the latter from the outside.

 Obviously, the connection of the oxygen bleeding line (structural elements 28, 27, 25, 26) with the additional 18, and not with the main 17 output of the generator 3 should be structurally ensured, since only in this case when the generator 3 provides the minimum oxygen production rational use of oxygen for respiration, even taking into account its partial release into the atmosphere. If the oxygen bleed line was connected to the main output of the generator 3, a significant part of the oxygen generated in the maximum capacity mode (output 17 is open, output 18 is closed) would be vented to the atmosphere through the bleed line or removed from the respiratory circuit through valve 21 after significant oxygen accumulation in the respiratory circuit and a significant change as a result of this initial composition of the gas mixture in the direction of increasing oxygen concentration in it.

 Thus, in the proposed apparatus, oxygen intake into the respiratory circuit can be controlled practically over the entire load range, while due to the balanced supply and consumption of oxygen in the respiratory circuit, an almost constant oxygen concentration is maintained at the required level, for example, at the initial level, acceptable from a physiological point of view. This, in turn, determines the comfort of breathing and eliminates the possibility of oxygen poisoning during prolonged exposure during the entire duration of the protective action of the respiratory apparatus.

Claims (1)

 A RESPIRATORY DEVICE ON CHEMICALLY RELATED OXYGEN, containing a front part, a carbon dioxide absorber, a breathing bag communicated with a breathing bag through a calibrated hole in a buffer tank, one of the walls of which is rigid, a regulator in the form of a two-position shutter mounted in a buffer tank on a rigid wall, and oxygen generator with primary and secondary outputs located on opposite ends of the generator and communicated with the buffer capacity through two nozzles interacting with the shutter characterized in that, in order to ensure comfortable breathing in the apparatus by maintaining the oxygen concentration in the respiratory mixture at a physiologically acceptable level, the additional output of the oxygen generator is additionally communicated with the atmosphere through a series-installed check valve and a tension valve associated with the one placed in the breathing bag tension element.