RU2073530C1 - Revivescence device for compulsory artificial breathing - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: the device includes means to supply gas mixture for patient connected by pneumatic conductors and locking elements, aspiration reservoir and slide valve gas distributor. Reservoir is made as rigid carcass and membranous partition. Slide valve gas distributor is supplied with pneumatic switching mechanism. EFFECT: higher efficiency. 5 cl, 4 dwg

Description

 The resuscitation apparatus of forced artificial respiration is a gas distribution device designed in the form of a lightweight, compact and small-sized device that relates to medical equipment and works only from the lifeguard’s breathing, therefore it can be used by any person to carry out artificial ventilation of the lungs when providing first aid in extreme conditions to save victims who are in a terminal state directly in the focus of mass destruction I ("Disaster Medicine"), as well as in everyday conditions at the initial stages of medical evacuation for the production of mechanical ventilation in the field, at feldsher-obstetric stations, ambulances, geological parties, water stations, during mountain rescue operations, etc.

 The basis of the invention is the task to create a reliable and simple mechanical device that works only due to the lifeguard’s breathing and does not require other types of energy, with which it is possible to produce artificial ventilation of the victim’s lungs by forcing both the lifeguard expiratory air and atmospheric air into its lungs ( or other gas mixture), as well as forced or spontaneous evacuation of expiratory air from its lungs with emission into the atmosphere, as well as reliable isolation of the expired air when Doha rescuer and increase the reliability of switching the phases of inhalation and exhalation of the victim.

 This goal is achieved by the fact that the apparatus contains a means of supplying a breathing mixture with a supply line, a breathing tank with inspiration and expiration chambers separated by a hermetically sealed membrane septum, communicated air supply and exhaust lines and inspiration and expiration lines through a gas distributor in the form of a spool double action respectively with the atmosphere and means for connecting the victim, the main adjustable membrane switching mechanism connected to the gas distribution the body and communicated with the supply line of the respiratory mixture, and is also additionally equipped with four three-way valves made in a single rotary core and an additional switching mechanism similar to the main one and connected to the main gas distributor, made in the form of a single body and a single spool, to one end of which is rigidly attached the membrane of the additional switching mechanism, while the lines of inspiration, expiration, supply and exhaust of atmospheric air are equipped with additional similar air with lines connected to the body cavity and connected in parallel to the main one by means of corresponding three-way valves, the additional supply line of the mixture in communication with the additional switching mechanism, and the main supply line of the mixture with the patient’s inhalation line through one of the three-way valves, the mixture supply means being made in as an element for connecting the resuscitator, and the patient’s exhalation line is equipped with a suction nozzle with a shut-off valve. The apparatus is also equipped with six flap valves, three of which are shut-off valves, two of which are installed with the possibility of communicating respectively the exhalation line and the additional mixture supply line with the atmosphere, and the third is installed in the inspiration line.

The device of the resuscitation apparatus of forced artificial respiration and its principle of operation in two functionally different modes is illustrated in the drawing. In FIG. 1 shows the device in the exhalation position of the resuscitator and forced inhalation of the victim with the delivery of the exhalation air of the resuscitator into his lungs; in FIG. 2 the same in the inspiratory position of the resuscitator and forced exhalation of the victim into the apparatus expiration chamber; in FIG. 3 the same in the position of the rotated block of three-way valves and switching the device into operation
inhalation of the resuscitator through the inspiratory valve from the atmosphere and the spontaneous exhalation of the victim into the atmosphere through the valve exhaling into the atmosphere; in FIG. 4 the same in the exhalation position of the resuscitator into the exhalation chamber and the forced supply of atmospheric air (or oxygen, or another gas mixture supplied to the intake pipe) from the inspiration chamber into the victim's lungs.

 The resuscitation apparatus of forced artificial respiration contains the mouthpiece 1 of the rescuer (face mask) and the mask of the victim 2, a breathing tank 3 with an inhalation chamber 4 and an exhalation chamber 5 separated by a membrane partition 6 sealed in a rigid case, a gas distributor made in the form of a single body 7 with eight through, coaxially arranged channels 8 to 15 and respectively connected externally to fittings for connecting the gas pipelines indicated below, and inside the housing 7 there is a spool 16 with through transverse channels-grooves 17 20.

 At the ends of the spool housing 7 there is a spool chamber 21 of additional switching mechanisms and a chamber 22 of the main switching mechanism with membranes 23 of the main and 24 additional switching mechanisms fixed to their ends to the ends of the spool by their centers. In this case, the submembrane space of the chamber 21 and the membrane-spool space of the chamber 22 have decompression holes 25 and 26.

 Adjusting the length of the translational movement of the spool 16 for combining the channels of the valve body 8 15 with the channels of the valve 17 20 is carried out by adjusting screws 27 and 28.

 A common duct (rescue inlet and outlet) 29 connects the mouthpiece 1 (or face mask) through a three-way valve 30 to a valve box 31 in which a common inspiration shut-off valve 32 is located. From the valve box fitting 31, the breathing mixture supply line, represented by the gas line 33, leads to the channel 14 of the housing 7, where the valve 34 is located, which cuts off the reverse movement of air from the victim to the resuscitator.

 An air duct 35 departs from the gas line 33, connecting the supply line of the respiratory mixture 33 with the submembrane space of the spool chamber 22.

 The lateral fitting of the three-way valve 30 is connected by an additional pneumatic line 36 to the fitting of the channel 15 of the housing 7, and on the opposite side the channel 15 opens into the valve box of the valve 37 of the breathing device of the resuscitator from the atmosphere. From the same pneumatic line 36 there is a gas line 38 leading to the membrane-spool space of the spool chamber 21 and a gas line 39 of the exhalation of the resuscitator, leading to the fitting of the channel 12 of the housing 7 of the spool. From the opposite fitting of the channel 12 there is a parallel pneumatic conduit 40 to the side fitting of the three-way valve.

 An atmospheric air supply line 41 connects the inspiration chamber 4 through a three-way valve 42 to the fitting of the channel 8 of the housing 7.

 From the side fitting of the three-way valve 42, there is an additional pneumatic line 43 of atmospheric air inlet to the fitting of the channel 9 of the housing 7, and on the opposite side of the housing 7, the channels 8 and 9 are connected by a common box of the inlet pipe 44. The exhaust gas pipe 45 connects the box of the exhaust (bleed) valve 46 through a three-way crane 47 with a fitting for channel 10 of the housing 7. From the side fitting of the three-way valve 47 there is a parallel (main and additional) output line 48 connecting the three-way valve 47 with fittings of the channels 10 and 11 of the housing 7. With bying side channels 10 and 11 share a common outlet box 49.

 The gas line 50 of the exhalation line through the exhalation valve 51 connects the exhalation chamber 5 through a three-way valve 52 and the valve box of the injured person’s spontaneous expiration valve 53 with the fitting of the channel 13 of the valve body 7.

 The gas line 54 of the inhalation of the victim connects the mask 2 of the victim with the fitting of the channel 14 of the body 7, and the gas pipeline 55 of the exhalation of the victim connects the mask 2 with the fitting of the channel 13 of the case. In the gas line 55 exhalation has a suction pipe 56 with a shut-off valve 57 to drain the liquid.

 The resuscitation apparatus of forced artificial respiration works as follows.

 In the first version of the operating mode, when the common core of the three-way valve block is turned all the way (in the drawing clockwise, Figs. 1 and 2), the nasolabrous anesthetic mask 2 is tightly fixed on the victim’s face using the neck rubber belt provided with the mask. The mouthpiece 1 is taken by the resuscitator in the mouth, (or puts on a facial rubber mask with a mouthpiece such as a light-diving one when assisting in a gassed atmosphere).

 When the rescuer exhales (Fig. 1), his exhale air through the main gas mixture supply line, namely through the gas line 29 to the direct channel of the three-way valve 30 enters the valve box 31, while the inspiration valve 32 closes and the exhalation air enters through the gas line 33, through the valve 34 to the channel 14 of the housing 7, and if at that time the valve 16 is in a position where the channel 14 of the housing is disconnected from the channel 20 of the valve, then the breathing air of the lifeguard will rush through the duct 35 into the valve chamber 22, will press on the membrane 24, which will bend and move spool 16 until the channels 14 of the case and 20 of the spool are combined and further through the gas pipeline 54, it enters the mask 2 of the injured person and then forcibly goes into his respiratory tract, because there are no channels 13 of the body and 19 of the valve connected to the gas pipeline 55;

 At the time of the exhalation of the resuscitator, when the spool 16 is in the extreme (in the left drawing) position, the body channels 8, 10, 12 are also combined with the spool channels 17 19, as a result of which gas is exchanged in the inspiration chamber 4 and the expiration chamber 5 due to the membrane elasticity 6 .

 When inhaling the resuscitator due to the increased pressure in the gas pipelines of the apparatus, the valve 16 cannot immediately come to the right position and the exhaled air of the injured person can partially enter the lungs of the resuscitator, which is unacceptable. In order to eliminate the reverse air flow, a valve 34 is placed in the breathing mixture supply line, which closes at the very beginning of the inspiration of the resuscitator, and negative pressure is created in the submembrane space of the spool chamber 22, the spool 16 will move (to the right in the drawing) to the stop screw 28 (Fig. . 2), while channels 9, 11, 13 (and 15) of the casing are combined with channels 17, 18, 19 (and 20) of the spool, respectively. But there is no air path through the gas pipelines 36, 43, 48, since they are blocked by three-way valves 30, 42, 47, respectively. Then the air from the inspiration chamber 4 will be sucked out and flow through the inspiration valve 32 into the valve box 31 and from there through the direct channel of the three-way valve 30 will go to the mouthpiece 1 of the resuscitator. At this time, a vacuum is created in the chamber 4 of the inspiration, the elastic (rubber) membrane wall will bend towards the chamber 4 and negative pressure will be created in the chamber 5 of the exhalation, due to which the expiratory air will be forced to come from the respiratory tract of the victim through the mask 2, gas pipeline 55 , combined channels 13 of the housing and 19 of the spool, along the direct channel of the three-way valve 52, the exhalation valve 51. The exhalation valve 46 is closed at this time. Upon subsequent exhalation of the resuscitator, gas exchange again occurs in chambers 4 and 5, as was said above, i.e. chamber 4 is filled with atmospheric air for inspiration of the lifeguard, and chamber 5 is simplified.

 Switching the device to another mode of operation of forced supply of atmospheric air (or oxygen, or any other gas mixture supplied to the inlet pipe 44) into the lungs of the injured person and exhaling it spontaneously is done by turning the core of the three-way valve block 90 degrees to the stop (in the drawing counterclockwise ) (see Figs. 3 and 4). Switching is advisable to be done after exhaling the resuscitator, although compliance with this rule is not necessary. For convenience, we consider the option that the device is switched after exhalation, then when the lifeguard is inhaled, negative pressure will be created in the gas pipelines 29, 36, 38 and 39, or the spool 16 is in the left position, as in FIG. 1, and the channels 15 of the housing and 20 of the spool are disconnected, air cannot come from the chamber 5, or it is not there, and if it does, then the valve 51 closes its path, then negative pressure will also be created in the membrane-spool space of the spool chamber 21, as a result, the membrane 23 will bend and move the spool 16 to the right until the stop of the screw 28 (Fig. 3). Channels 9, 11, 13, 15 of the housing will be combined respectively with the channels 17 20 of the spool, and as a result, atmospheric air through the valve 37, channels 15 and 20, the gas pipe 36, the three-way valve 30, the gas pipe 29 and the mouthpiece 1 will be inhaled to the resuscitator. At this time, as a result of combining the channels 9 and 17 and the channels 11 and 18, the chamber 4 will be filled with atmospheric air and the expiratory air will be ejected from the chamber 5. As a result of combining the channels 13 of the body and 19 of the damper valve, the expiratory air from the injured lungs will come out through the exhalation valve 53 due to the elasticity of the lung tissue and the collapse of the chest.

 Gas exchange in the chamber 4 of the inspiration and chamber 5 of the exhalation will occur every time the inspector lifts, with the only difference being that the functional roles of chambers 4 and 5 changed with the rotation of the core of the three-way valve block: now chamber 4 has become the inspiration chamber of the victim, not the resuscitator, and the chamber 5 became the exhalation chamber of the resuscitator, and not the victim, as it was before the switch.

 When the resuscitator is exhaled, the valve 37 closes the path to the atmosphere, in the gas pipelines 29, 36, 38 the pressure rises, the membrane 23 bends and moves the spool 16 to the left, the channels 12 of the housing and 19 of the spool, as well as the channels 14 and 20, will be combined and the expiration air of the resuscitator through the valve 52, the valve 51 will enter the exhalation chamber 5, but since the air outlet through the valve 46 is closed, because the channels 11 and 18 are disconnected (Fig. 4), the membrane 6 will bend and expel atmospheric air from the chamber 4, which the valve along the supply line of the mixture and the inspiratory line of the patient it will enter the lungs completely, through the air duct 35 it will enter the chamber 22 and support the spool.

 Switching the device to the initial mode of operation (forced inhalation of the injured person with the expiration of the resuscitator and forced expiration into his lungs) is performed by turning the core of the three-way valve block in the opposite direction until it stops (clockwise in the drawing). It is advisable to perform this reverse switching after inhalation of the resuscitator, although non-observance of switching relative to the phases of breathing does not entail any particular consequences: the resuscitator simply feels difficulty in inhaling or exhaling and changes the phase of breathing by inhaling or exhaling not through the mouthpiece, but through the nose.

 In the production of mechanical ventilation by this device, it is recommended that after several breathing cycles (10 12), the device is switched from one mode to another - this gives the best resuscitation effect.

 The device can be used to suck out fluid from the lungs while helping a drowning man. To do this, the device is set into the operating mode of forced inhalation and exhalation of the injured, a long, durable reinforced rubber tube (should be in the spare parts) is put on the end pipe of the two-way valve 57, the other end of which is put on the neck of the bottle, the two-way valve 57 is set to the “open” position a nasal anesthetic mask is put on and tightly fastened with a belt on the victim, the lifeguard takes a mouthpiece in his mouth and takes a few active deep breaths. The liquid from the victim’s lungs is sucked off and drains into a bottle, which should be lower than the victim’s head, turned on its side or face down.

 The device can also be used to assist and evacuate victims from the lesion in a polluted atmosphere (accident in a mine, chemical plant). In this case, the rescuer must have a face mask, a gas mask is attached to the inlet 44, the device should only work in the forced inhalation and exhalation mode.

 When assisting children, the resuscitator should have some experience and remember the features of children's breathing, constantly observe the excursion of the chest of the child, breathe more often and not take deep breaths and exhalations. To fill the "lack" of your breath with "breath for yourself", breathing through your nose, and not in the mouthpiece.

Claims (5)

 1. Resuscitation apparatus of forced artificial respiration, containing means for supplying the respiratory mixture with a line for its supply, a breathing tank with chambers for inhalation and exhalation, connected by lines of supply and output of atmospheric air and lines of inhalation and exhalation through a gas distributor made in the form of two spools, respectively, with the atmosphere and means for connecting the victim, the main adjustable membrane switching mechanism connected to the gas distributor and in communication with the supply line of the respiratory mixture characterized in that it is equipped with four three-way valves and an additional switching mechanism, similar to the main one and connected to the gas distributor, made in the form of a single housing and a single spool, while the inspiration, expiration, supply and exhaust air lines are equipped with additional similar pneumatic lines communicated with the cavity of the housing and connected in parallel to the main through the appropriate three-way valves, and the additional supply line of the mixture is communicated with an additional switch Luciano mechanism, a main line feeding the mixture to the inspiratory line of the patient through one of said three-way valves, wherein the means for feeding a mixture formed as a connecting element for a resuscitator.  2. The apparatus according to p. 1, characterized in that the chambers of inspiration and exhalation are formed by means of a septum membrane sealed in a rigid case.  3. The apparatus according to claim 1, characterized in that the center of the membrane of the additional switching mechanism is rigidly connected to one of the ends of the spool.  4. The apparatus according to claim 1, characterized in that the exhalation line of the victim is equipped with a suction nozzle with a shut-off element-crane.  5. The apparatus according to p. 1, characterized in that it is equipped with three shut-off valves, two of which are installed with the possibility of communication respectively the exhalation line and the additional supply line of the mixture with the atmosphere, and the third is installed in the exhalation line,

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