RU2084215C1 - Apparatus for artificial ventilation of lungs - Google Patents

Abstract

FIELD: emergency medical care; medicine of catastrophes. SUBSTANCE: proposed apparatus comprises ventilation frequency generator, operating modes selector, unit for putting injector into operation, per-minute ventilation controller, ventilation frequency controller, injector, valve box, and breathing gas supply unit. Ventilation frequency generator is made in form of two-way valve driven by spring-urged three-arm lever, two rigidly coupled piston rods, and throttling membrane-type elements. Operating modes selector is formed as slide valve adapted to connect per-minute ventilation controller and ventilation frequency controller with pressure source, and also to connect suction line of injector with atmosphere, breathing gas supply unit being arranged at pipe line putting injector in communication with pressure source. EFFECT: all respiration parameters are controllable independently from each other, at independent frequency, thereby making it possible to use apparatus under in emergency situations. 3 cl, 3 dwg

Description

 The invention relates to medical equipment, in particular to a mechanical ventilation apparatus [IVL] operating in frequency, with adjustable respiration parameters and used for mechanical ventilation and inhalation in ambulances, rescue services and hospitals.

 Known ventilator "Pnevpak" [1] is a pneumatic pulse generator and contains a distribution valve with different areas, variable-volume cavities with differential pistons, filled through adjustable throttling devices, and a throttle device configured for a specific flow of respiratory gas. Differential pistons perform the function of switching the distribution valve and, accordingly, switching the device according to the phases of respiration.

 The disadvantage of the apparatus "Pnevpak" is the dependence of minute ventilation on adjusting the time of entry and exit and their ratio and a rather large mass. The device performs one ventilation function.

 Also known is a breathing apparatus [2] containing a controlled time unit with a gas source, regulating valves for respiratory rate and flow, connected to each other through engagement elements, patient valves, operating pressure and pressure relief.

 The ventilation frequency is controlled by the breathing rate valve, and the tidal volume by the flow valve. The ratio of the durations of inspiration and expiration is chosen constant and is determined by the values of capacities in the control lines of the switching valve for supplying respiratory gas to the patient.

 The disadvantage of the apparatus is that, with an obvious simplification of control, the apparatus is deprived of the possibility of providing an independent setting of the ventilation frequency and tidal volume due to the rigid connection of the adjustment valves of these parameters. At the same time, the physiology of each individual patient requires the installation of specific independent values of the respiration parameters.

 Known breathing apparatus [3] created on the basis of standard pneumatic elements and containing a regulator, two pneumatic relays, an inverter-amplifier, a device for connecting to the patient’s airways, an variable throttle for adjusting the respiratory rate and a valve for changing minute ventilation. The ratio of the duration of inspiration and expiration is regulated by the threshold of operation of the inverter of the amplifier.

 If the position of the minute ventilation valve remains unchanged and the inverter threshold changes, the fraction of the time of its on state in the breathing cycle during mechanical ventilation is variable and, therefore, the minute ventilation will also change.

 Known breathing apparatus "Oksilog" [4] manufactured by the German company "Draeger". The device, in addition to artificial lung ventilation, provides pulmonary-automatic supply of respiratory gas.

 The apparatus contains a reducer, an adjustable ventilation frequency generator [HHF] with a pneumatic toggle switch, a minute volume regulator, a pneumatic relay for turning on the respiratory gas, patient valves [non-reversible] operating pressure, pressure relief and a pulmonary machine connected in parallel to an automatic artificial ventilation unit. The device has independent adjustments to the minute volume and frequency of ventilation, with a constant ratio of the duration of inspiration and expiration 1: 1.5. The parallel connection of the pulmonary automaton to the artificial lung ventilation unit ensures its inclusion in any phase of breathing during a patient's respiratory attempt.

 However, in the absence of pressure at the inlet to the apparatus and the additional inspiration valve, the patient, when his own breath appears, is deprived of the opportunity to try to inhale from the atmosphere, which reduces the reserve functional capabilities of the apparatus. In addition, in the apparatus there is no adjustment of the percentage of oxygen in the respiratory gas when operating in the inhalation mode.

 At the same time, a large number of structural elements increases the dimensions and weight of the apparatus.

 The aim of the present invention is to increase reliability, obtain independently adjustable ventilation parameters and provide inhalation functions and reserve supply of respiratory gas, which will expand the functionality of the apparatus.

 To achieve this goal, the ventilation frequency generator [GCHV] is made in the form of a two-position valve device controlled by a three-arm spring-loaded lever, one of the shoulders of which is located between two pistons rigidly fixed to each other, mounted in the housing and forming cavities with its walls connected through throttle-membrane elements with outputs of the on-off valve device, which in turn are connected to the control cavities of the injector inclusion unit, and the operation mode switching unit in Full a valve connecting the pressure source to the input of the regulator and minute ventilation with inlet on-off valve device through the ventilation frequency regulator and the injector suction line to the atmosphere through metered orifice.

 Independent adjustments to minute ventilation and ventilation frequency at a fixed value of the ratio of the durations of inspiration and expiration are ensured by dividing the output pressure supply lines of the regulators to the injector and the ventilation frequency generator and the absence of mutual influence on each other's work.

 At the same time, a reserve respiratory gas supply device is located between the power source and the injector and allows for rapid inflation of the patient’s lungs or for rapid filling of the respiratory bag during inhalation.

 To maintain the volumetric flow of respiratory gas during mechanical ventilation and inhalation, the spool of the mode switch contains a metering element of a certain section.

 Placing the mode-switching unit on the line of entry into the apparatus allows disabling the hot water supply during inhalation and rationally using its resource.

 Placing the backup supply device outside the ventilation parameter control lines in the event of a malfunction of the regulators or the hot water heater provides additional backup functionality of the device.

 The invention is illustrated by drawings in Fig. 1 to 3, which shows a schematic diagram of the ventilator.

 The apparatus consists of a generator of ventilation frequency 1, switching nodes of operating modes 2, turning on the injector 3, minute ventilation regulators 4, ventilation frequency 5, valve box 6, which performs the function of a unit for connecting to a patient, and a reserve supply device 7.

 ГЧВ 1 contains a two-position valve device 8 with a valve 9 and two spring-loaded valves 10 and 11, a three-arm lever 12 and two rigidly connected pistons 13 and 14 with throttle-membrane elements 15 and 16. One of the arms of the lever 12 is located between the pistons 13 and 14, and the other two shoulders interact with the valve 9 and the spring-loaded latch 17.

 The operation mode switching unit 2 has a rotating spool 18 located in the housing 19 and closed by a cover 20. A lock 21 is mounted in the housing 19. The spool 18 has channels for connecting the pressure source to the regulators 4 and 5, mechanisms 3 and 7, and also metering holes 29, 30 and 47 for connecting the suction line to the atmosphere and a pressure source.

 Spool 18 has three fixed positions of mechanical ventilation, IN 50 and IN 100, corresponding to the operating modes of the apparatus, with automatic ventilation, inhalation with a respiratory mixture containing 50% oxygen and inhalation with pure oxygen.

 The injector switching unit 3 comprises a normally open on-off valve rigidly connected to the control membrane. Its output is connected through a check valve 24 to the injector 23.

 Valve box 6 includes a non-reversible diaphragm valve 25, an operating pressure valve 26, an additional inspiratory valve 27, and a positive expiratory pressure regulator [ПДКВ] 28.

 The backup feed device 7 is a spring-loaded valve with a power button, blocking the inlet pressure line 31.

Automatic ventilation [Fig. one]
The spool 18, made at the same time with the handwheel extending beyond the cover 20, is set to the ventilation position. At the same time, the spool 18 with its channels 32 and 33 provides respectively the connection of lines 34 and 35, 36 and 37, and the hole 29 of the suction line 38 of the injector 23 with the atmosphere.

 Oxygen from the source with a pressure of 0.4-1 MPa goes to regulators 4 and 5 through channels 22, 39, 40 and 34, 35. When regulator 4 is opened, gas is supplied through channels 36, 33 and 37 to the injector switching unit 3, and when opening of the regulator 5 at the input of the hot-water generator 1.

 The valve 9, pressed by the lever 12 using the lock 17 to the right seat, provides pressure to the control cavity 41 and to the throttle-membrane element 16. Oxygen through the open valve of the switching unit 3 and the check valve 24 enters the injector 23. The latter, sucking in atmospheric air through the metered hole 29 on line 38, delivers the gas mixture through a non-reversing valve 25 into the mask 43. An act of inspiration occurs.

 The maximum pressure generated by the apparatus is limited by the operating pressure valve 26.

 At the same time, the cavity 44 is being filled through the throttle-membrane element 16. The piston 14 moves to the left until it overcomes the force of the spring-loaded clamp 17. The valve 9 moves to the left and provides pressure supply to the control cavity 42 and to the throttle-membrane element 15. On-valve 3 blocks the flow of oxygen to the injector 23. Simultaneously with the switching of the valve 9, the valve 10 opens and pressure is released from the cavities 41 and 44 into the suction line of the injector. The device switched to exhalation.

 Pressure is released from the patient's lungs through a non-reversible valve 25 into the atmosphere. If necessary, the value of the positive pressure in the patient’s lungs at the end of exhalation [PDKV] can be set by the PDKV 28 regulator. At the same time, the cavity 45 is accumulating through the throttle-membrane element 15.

 The piston 14 moves to the right until it overcomes the force of the spring-loaded clamp 17. The valve 9 is thrown to the right. The exhalation act is over and the breathing cycle repeats again.

 If there is an attempt to inhale the patient in any act of breathing, as well as with a lack of volumetric supply, an additional inspiration valve 27 is provided for intake of the missing air from the atmosphere.

 To ensure lung inflation during mechanical ventilation [5] or rapid filling of the respiratory bag during inhalation, there is a backup supply device 7 for supplying oxygen to the injector 23 directly from the apparatus input line, bypassing regulator 4. In this case, the injector switching unit 3 and regulator 4 are protected by a check valve 24 from excessive exposure to inlet pressure.

 The filling rate of the cavities 44 and 45 is controlled by a regulator 5, which determines the frequency of minute ventilation. The flow sections of the chokes of the elements 15 and 16 determine the filling time of the cavities 44 and 45, that is, the time of the acts of inspiration and expiration, and the ratio of these sections is the ratio of these times.

 Regulator 4 sets the oxygen supply to the injector 23 and, therefore, the value of minute inhalation.

Oxygen-air inhalation [Fig. 2]
Inhalation is provided using a breathing bag 46, which is installed using a square in the valve box socket instead of a cork.

 When setting the handwheel of the operating mode switch to the IN 50 mark [Fig. 2] the spool 18 connects the channels 36 and 37 through the nozzle 47, while the channels 34 and 35 are disconnected, and the suction line of the injector 23 is connected to the atmosphere through the dosed hole 30. The hot water heater 1 is turned off.

 Oxygen is supplied through channels 22, 39, and 40 to the regulator 4 and then through channel 36 through nozzle 47 to channel 37, and then through the normally-open valve of switching unit 3 to the injector 23. The latter draws atmospheric air through channel 38 through a metered hole 30 and delivers the gas mixture with a constant flow rate to the valve box 6 and then to the breathing bag 46.

 The volumetric flow is regulated by regulator 4.

 When you inhale, the gas mixture is taken from bag 46. The exhaled gas is released through a non-reversing valve 25 into the atmosphere.

 During inhalation with pure oxygen [Fig. 3] the handwheel of the spool 18 is set to IN 100. The channels 34 and 35 are disconnected, the channels 36, 37 and 38 are connected by the spool 18 using channels with a nozzle 47. At the same time, the suction line of atmospheric air is closed. Oxygen enters the injector 23 through the channel 37 through a normally open valve of the switching unit 3 to the injector nozzle and through the nozzle 47 through the channel 38 to the injector suction line and then to the breathing bag 46.

 The regulation of the volumetric flow of oxygen is carried out, as in other cases, by the regulator 4. The through section of the nozzle 47 is selected in such a way that the volumetric flow supplied to the mask, in the mode of ventilation and inhalation at a constant position of the regulator 4, remains constant.

Information sources:
1. Magazine "Anaesthesia", 1977, Volume 32, pages 34-40.

 2. The patent of Germany 2735555, MKI A 61 M 16/00, publ. 09.09.82 g.

 3. A.S. USSR 1156686, MKI A 61 H 31/02, publ. 05/23/85

 4. Prospectus of the company "Drager" P550312 from 02.12.85

 5. Zilber A.P. "Mechanical ventilation in acute respiratory failure", Moscow, ed. Medicine, 1978, p. 88.

Claims (4)

 1. The artificial lung ventilation apparatus comprising a ventilation frequency generator with a ventilation frequency regulator at its inlet, a minute ventilation regulator connected to the injector inlet through its switching unit, an operation mode switching unit and a valve box, characterized in that the ventilation frequency generator contains a two-position valve device with a switching valve and two spring-loaded pressure relief valves, two pistons rigidly fastened to each other, forming cavities with the walls of the housing, two dross flax-membrane element and a spring-loaded three-arm lever, one of the shoulders of which interacts with the switching valve, the end of the other lever is located between the pistons, while the outputs of the on-off valve device are connected to the control cavities of the injector inclusion unit and through the throttle-membrane elements with piston cavities, and the operation mode switching unit is made in the form of a spool connecting the pressure source with the input of the minute ventilation regulator and the input of the on-off valve device CTBA through ventilation frequency regulator and the injector suction line to the atmosphere through metered orifice.  2. The apparatus according to claim 1, characterized in that it is equipped with a backup gas supply unit and a check valve, wherein a backup supply unit is located between the pressure source and the injector, and a check valve between the injector and its inclusion unit.  3. The apparatus according to claim 1, characterized in that the spool for switching the operating modes is equipped with a metering element for maintaining the volumetric flow during the transition from mechanical ventilation to inhalation.  4. The apparatus according to p. 1, characterized in that the valve box is equipped with a valve to provide additional air from the atmosphere.

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