DD212186A1 - medical ventilator - Google Patents

Abstract

The invention relates to an optional pressure or. Volume flow-controlled ventilator, especially for the treatment of early-born and infants, which works without the use of additional I / E valves and PEEP valves with only one control valve. The object is achieved by removing the respiratory gas at the negative pressure outlet 9 of an injector 2 arranged between the respiratory gas source 1 and the control valve 3. Fig.1 illustrates the pressure control loop. The pressure is measured in the pressure transducer 6 u. fed to the actual value input of the pressure regulator 16. The setpoint receives pressure regulator 16 from the ventilation pattern generator 7. Pressure regulator 16 in turn controls the control valve 3 via a power amplifier 19. By an additional return of the output signal of the volume flow converter 5 to a second setpoint input of the pressure regulator 16, a negative pneumatic input resistance can be generated, whereby the tube resistance can be compensated. Because of the very low compressible volume, the device also enables high-frequency ventilation in addition to conventional ventilation modes. When using an evaluation unit 12, the device can be used during therapy or autonomously for the diagnosis of respiratory mechanics by the forced oscillation method.

Description

Title of the Invention Respiratory Device

Field of application of the invention

The invention relates to a ventilation device in which volume flow and pressure of the respiratory gas can be regulated automatically in accordance with predetermined reference variables. In addition, this device can also be used for investigations of Atemmechanilc by the method of ^ forced oscillation.

Characteristic of the known technical solutions

Ventilators with automatic control of volume flow or pressure, according to predetermined reference variables, have significant advantages over non-regulated devices.

According to the state of the art, this regulation is realized by obtaining an actual signal by means of pressure and volume flow transducers arranged in the immediate vicinity of the patient connection, which is compared with predetermined, generally time-variable, nominal values (reference variable). The difference between the two signals, the so-called control deviation, influences via a controller a control valve located between the respiratory gas source and the patient connection, the so-called actuator, whereby the respiratory gas supply is changed in such a way that the best possible correspondence between the first and second

values' (A? 105563). Regulated ventilators are characterized by the fact that virtually all known ventilation modes can be realized by almost any setpoint specification.

By alternative choice of volume flow or pressure control between Inapirations- and Sspirationsphase can also be achieved more favorable, not achievable with non-regulated equipment ventilation procedures (DT 244 130 6 AI).

A disadvantage of these control methods, in which the actuator is between the source of breathing gas and the patient connection, is that they need an additional inspiration / Sxpirationsventil, called I / E valve to separate the expiration and inspiration air. In addition, for the generation of the PSSP. (positive ejad expiratory "pressure) or" "in the weaning phase indicated CPAP breathing air (continuous positive airway pressure) still requires additional PEEP valves, which in the

general spring-loaded work * -v

According to a performance according to DE 2oO 306 3 A1, the OPAP generation takes place by means of a gas jet tube. '·

Both methods, in particular the latter bring an additional resistance in the system, which must be overcome by the patient bsi the spontaneous rate in the modes IMV (intermittent mondatory ventilation) or OPAP, in addition, that through these valves and the necessary tubing connections the compressible volume can take on significant values.

This is one of the reasons why highly profiled devices designed for adult adiposity are of limited use in preterm neonatal ventilation. "This high compressible volume is also one of the reasons why it is extremely difficult to control the ventilator. Range of these controlled ventilators to extend the modern ventilation of high-frequency ventilation. Another disadvantage of these devices is that, due to the large number of pneumatic elements used, the steri-

liaation is very expensive.

In WP 57 403 or DS 149 167 1 B2 it is proposed to attach the patient port to the suction nozzle of an injector which is connected between the respiratory gas source and a subsequent pneumatic amplifier. However, this principle does not allow regulation, but shows two-point behavior.

Object of the invention

The aim of the invention is to provide a ventilator, in particular for premature babies and infants with control of volume flow V or pressure p, which without use. of I / S valve and PSEP valve only one actuator needed. The invention is also intended to solve the problem that with minimal dead space in addition to the conventional types of ventilation and high-frequency ventilation is possible. Furthermore, during the course of therapy, diagnostic phases for the examination of the respiratory mechanics are inserted according to the forced oscillation method, or the device is used autonomously for the examination of the respiratory mechanics according to this method.

Explanation of the essence of the invention

This object is achieved in that the patient connection is arranged at the positive pressure output of an injector located between the respiratory gas source and the control valve. The volumetric flow and pressure are converted into analyzable signals near the patient connection in a volumetric flow converter and a pressure converter and alternatively provided to a controller as an actual value. The controller receives the setpoint values from a ventilation pattern generator and, in turn, controls a control valve according to setpoint-actual value comparison. Subject to this principle is both sine control of the flow to the patient and 'a pressure control possible. Since the regulators required for the alternative control variables generally have different time behavior, either separate regulators with corresponding

Switching devices or a controller with switching devices for the setpoint-actual value difference and the time constants are used «With advantage, a digital control can be used. The coordination of the regulator and the ventilation pattern generator is carried out via a central controller. This principle can be carried out purely pneumatically, with the latter variant being preferred. To protect against unwanted overpressure and underpressure, a safety valve group is used.

By the method according to the invention, ie the connection of the patient at the negative pressure outlet of the injector, it is achieved that a negative pressure acts on the patient connection when the control valve is open. This pressure can be varied continuously up to the desired positive pressure values depending on the throttling of the control valve.

Thus, without the use of 'additional I / E' vents and PESP valves, the desired type of ventilation as well as a GPAP breathing aid can be realized once only by varying the opening of the control valve. Due to the - high control gain, the patient breathes during spoutation (IMV, GPAP) against a negligible resistance of the ventilator. In addition, the compressible volume of the ventilator according to the invention is so low that with this in addition to the conventional types of ventilation and high-frequency ventilation is possible.

So you get a device, which is predestined because of its universality especially for the ventilation of premature and newborns. It is advantageous that because of the simple gas flow and the sterilization effort is significantly reduced.

A further advantage is that in the Palle of the pressure control by a feedforward of the Vo1urnenstromsignales to the Soll? Jerteingang the pressure regulator, a negative Resistance of VentilationsHgerates with respect to the patient connection can be achieved, whereby the resistance of the supply to the tube and the 'Tubua itself

can be compensated. This allows the use of Englumiger feed hoses to the tube and associated further reduction of harmful dead space, Moreover, the proportion of the work of breathing, which must be applied in spontaneous breathing to overcome the Tubusresistance reduced. Since in the injector strong dependence of the pressure at the Untardruck-output on the volume flow of the patient, in a further embodiment of the invention, a further return of the VoIu- menstromsignales made on the input of the control valve, whereby this influence can be compensated. It is convenient to frequency-correct the volume flow signal, which function is performed by a transmitter. The choice of the transfer function depends on the transfer behavior of the members and the controlled system.

Since the device can be structurally very small, it is possible to accommodate this in the immediate vicinity of the tube, in premature babies and infants in the incubator directly next to or above the head.

By arranging the pressure transducer, seen from the patient terminal, in front of the volumetric flow transformer needs to be placed on a low resistance of the Volumenstromwandle rs no value. This makes it possible to use very robust disinfection-friendly volume flow transducers.

Furthermore, it proves to be advantageous to use the signal of the volume-flow converter for the triggering of triggering, as required in assisted ventilation or in synchronized ILiV. The trigger pulse is generated during the gullet passage of the output signals of the volumetric flow converter when changing from expiration to inspiration.

Since the proposed principle enables pressure or volume flow oscillations of lower amplitude up to high frequencies (about 40 Hz), it can, without deviating from the principle of the invention, also be used for the diagnosis of respiratory mechanics.

are set, in particular for the so-called "forced oscillation method". This opens up the possibility of checking the respiratory-mechanical situation of the patient by inserting short diagnostic phases during respiratory therapy without disconnecting it from the device. "All that is required is an evaluation of the impressed pressure and volume flow signals according to known methods in an evaluation unit." The command variable is also provided here by the ventilation pattern generator. Of course, the device can also autonomously for the diagnosis of respiratory mechanics after the o.g. Procedures are used.

embodiment

The solution according to the invention will be explained in more detail with reference to an embodiment

In the drawing show ^: "

FIG. 2 shows a diagram of the control circuit for the pressure control. FIG. 2 shows a more detailed illustration of the ventilator

The exhaust gas passes from a breathing gas source 1 to the pressure side of an injector 2. Die'Euslaßdüse 13 from the injector 2 forms with the end face of a closed-sided thin-walled tube, which is the baffle plate 14, a nozzle-baffle plate system, which in conjunction with the electromechanical system 15 operatively corresponds to the control valve 3 in Fig. 1. The overall system corresponds to a nozzle-flapper system with a suction effect. Instead of the nozzle-baffle plate system, other, known to those skilled adjustable throttle elements, such as ball valves, conical valves, etc. can be used. The negative pressure outlet 9 of the injector 2 is connected to a patient port 8 via a volume flow converter 5. Zwischen'beiden the sensor of the pressure transducer 6 is arranged t.

The safety valve group 11 protects the patient in the event of an accident from any possible under- or overpressure,

The safety valve group 11 is located in the embodiment before the volume flow converter, but may also be arranged after this.

The output signal of the volumetric flow converter 5 reaches the actual value input of a volumetric flow controller 17, where it is compared with the nominal value coming from a respiration pattern generator 7.

The output signal of the volumetric flow regulator 17 acts via a changeover switch 18, to the input of a power amplifier 19} whose output is in turn connected to the electrodynamic system 15. The same also applies to the reference actual value comparison in the pressure control loop. The changeover switch 18 switches the output of the volumetric flow regulator 17 to the input of the power amplifier 19 in the case of nominal voltage control, and in the case of pressure control it switches the output of a pressure regulator 16 to the input of the power amplifier 19.

In addition, the output signal of the volumetric flow converter via an adjustable attenuator with Frorsquenzgangkorrektür 20 to the second setpoint input of the pressure regulator 16 is performed. As a result, the tube resistance can be more or less compensated for pressure control. To reduce the dependence of the pressure at the negative pressure outlet 9 from the volume flow through the patient port 8, the output signal of the volume flow converter is also fed via a transmission element 22 to the second input of the power amplifier 19.

The attenuator 20, switch 18, and respiratory pattern generator 7 are all coordinated by a central controller 10 in their interaction, which is illustrated in Fig. 2 by corresponding connections.

D.arüberhinaus the output signals of the Volumenatromwandle r a 5 and the pressure transducer 6 to the central control SS leads to control the connection with the information given by a control panel 21 the timing of the central controller 10 and their alarm regime.

The outputs of the pressure transducer 6 and volume flow transducer 5 are further connected to the inputs of an evaluation unit for diagnosis of respiratory mechanics 12, which in turn is in communication with the central controller 10.

A second exemplary embodiment provides for realizing the principle of operation of central controller 10 and ventilation pattern generator 7 by means of a microcomputer with a corresponding interface.

In a third embodiment, the function of the volume flow regulator 17, pressure regulator 16, the switch 18, the attenuator 20 and the transmission member 22 is realized by the microcomputer.

Claims (8)

invention claims 1. ventilator, in particular for premature babies and infants, in the volume flow or pressure of the respiratory gas
while inspiration and expiration is automatically controlled according to predetermined set values by a ventilation generator generator, which for this purpose contains a central control, bridge and flow converter close to the patient connection, operating elements and regulators, characterized in that the respiratory gas source. (1) via an injector (2) with a the
Actuator of a control circuit forming control valve (3) and the negative pressure outlet (9) of the injector (2) via a volume flow converter (5) to the patient port (8) is connected. - 2 - 4NC Output connected to the second input of the power amplifier (19), 2. Respirator according to item 1, characterized in that. Injector (2) and control valve (3) is realized by a nozzle-flapper system with ejector effect. 3 »ventilator according to item 2, characterized in that the baffle plate (14) is electrodynamically movable. 4 «ventilator according to points 1 to 3, characterized in that the measuring point for the pressure transducer (β) between the volume flow converter (5) and patient port (8) is located. 5. ventilator according to the points 1 to 4, characterized in that in pressure control of the output of the volume converter (5) with the input of an adjustable
Attenuator with frequency response correction (20) and whose output is connected to a second setpoint input of the pressure regulator. 6. A respirator according to the items 1 to 5, characterized in that the output of the vol-lumen-t romwandle rs (5) with the input of a transmission element (22) and its 7. A respirator according to item 1, characterized in that it by using an evaluation unit (12) either
Autonomously or temporarily during respiration for the diagnosis of respiratory mechanics by the method of forced
Oscillation is used. 8, respirator according to item 1, characterized in that the triggering of the trigger pulse in assistive
Ventilation and SIMY, which in turn initiates the inspiration phase, by the STulldurchgang the output signal
of the volume flow transducer (5) takes place when changing from expiration to inspiration. - Here are 2 sheets of drawings -