DE19708094A1 - Breathing apparatus with oxygen enrichment for patient - Google Patents

Abstract

The apparatus has a delivery device (2) which sucks breathing gas via an input line (3) and pumps it into an output line (6), a branch aperture (9) from the output line for a partial flow via an outflow valve (10) and at least one oxygen source (12) connected to the breathing apparatus. A return line (11) from the branch aperture to the input line enables gas to flow from the branch opening to the input line. The oxygen source is connected to the circuit contg. the input line, output line and return line upstream of the branch aperture.

Description

The invention relates to a ventilation device with the features of Preamble of claim 1.

A ventilator with a conveyor, which ambient air sucked in via an inlet line and into a patient leading breathing tube pumps is known from US 2,918,917 become. With the conveyor of the known ventilator inside the breathing tube and on the breathing tube connected breathing mask a certain excess pressure for support spontaneous breathing activity of a patient. To adjust the Overpressure is between the delivery device and the breathing tube Outflow opening provided, which are partially opened by means of a valve can. Depending on the degree of opening of the valve and via the outflow opening outflowing partial gas stream, decreases or increases the Ventilation pressure on the breathing mask. The well-known ventilator works in the so-called excess gas operation, in which the patient Unused gas escapes completely into the environment.

Should such a ventilator with a mixture of oxygen and Air can be operated, and the oxygen in a certain If a percentage of the ambient air is mixed in, a large part of the Gas mixture directly through the discharge opening into the environment and stands therefore no longer available for ventilation of the patient.

A respirator with ambient air is known from WO 87/01 599 sucking turbine known, which an oxygen / air-gas mixture delivers a patient. The breathing gas in the intake area of the turbine return line is not provided with this ventilator.

The invention has for its object to such a ventilator improve that an oxygen admixture with the breathing gas lowest possible gas loss and good concentration consistency.

The problem is solved with the features of claim 1.

The advantage of the invention is essentially that Return of part of the inhaled breathing gas to the area of the Intake side of the conveyor and the simultaneous metering of Oxygen from an oxygen source in the feedback loop, a good one Adjustability of the oxygen concentration in the breathing gas is achieved.

The conveying device is preferably at a constant conveying capacity set. But it is also possible to start with the conveyor to operate a minimum delivery rate and then the delivery rate to be adjusted according to need. This will reduce power consumption which increases the life of the ventilator during battery operation.

Advantageous embodiments of the invention are in the subclaims specified.

A buffer volume in the line is expediently the Arranged input line, and the return line and / or the Oxygen sources are connected to the buffer volume. By the Buffer volume creates a kind of mixing chamber in which Sucking in ambient air through the conveyor and that Recirculating part of the extracted breathing gas, a permanent one Gas circulation is present. By adding oxygen to it Buffer volume takes place after a short time due to the constant gas circulation a good mixing of the ambient air with the metered Oxygen instead. The oxygen can also be added before or after the buffer volume in the area of the input line or in The return line is pulled. Because of the bypass-like Redirection of the breathing gas via the return line into the buffer volume the gas loss compared to an arrangement with an open discharge opening minimized.  

The size of the buffer volume depends on the type of metering Oxygen in the through the inlet line, the outlet line and Return line formed circuit dependent and is determined by how fast the oxygen supply to the variable course of the gas flow in the Outgoing line can follow. If the oxygen supply is essentially follows the course of the gas flow in the outlet line is not significant buffer volume required, so that in many cases Internal volume of the conveyor, the input line or Return line sufficient as buffer volume. The largest buffer volume is on the other hand required for continuous metering of oxygen.

A control unit that actuates the oxygen source is advantageous provided which is connected to a flow meter that the Gas flow registered downstream of the outflow opening and a delivers the corresponding first measurement signal to the control unit. Corresponding the amount of gas flow measured, more or less oxygen is in dosed the buffer volume.

The metering of oxygen into the buffer volume can be done continuous and proportional to minute ventilation, proportional to Minute ventilation during inspiration or proportional to Breathing gas flow can be made. In proportion to the dosage Breathing gas flow has the possibility of a strictly proportional dosage or a dosage with a certain time delay, d. H. slightly less Oxygenation at the beginning of inspiration and more at the end of inspiration.

Advantageously, alternatively or in addition to Flow meter the setting of the oxygen content in the breathing gas by means of a Oxygen sensor can be made in the outgoing line, the one outputs the second measurement signal to the control unit. The second measurement signal is used as a further parameter for the oxygen source.

It is particularly advantageous to use the conveyor device as a turbine drive to execute. With the turbine drive, that of a patient  required amount of gas in a simple manner and with a good dynamic range suck in the environment.

The outflow valve is advantageously in the form of a membrane valve executed. Such valves work so that the membrane on one side a certain force is applied while the other side closes an outflow opening under the action of the force. With a Membrane valve can be a wide dynamic range in ventilation to cover frequencies of 10 Hertz and higher. With such a Valve can have a flow resistance of less in the outflow opening than 2 mbar / (L / s) (pressure change / flow change). The The ventilator then works as a very low pressure source Internal resistance. This is particularly the case with pressure-oriented ones Ventilation procedures such. B. CPAP, Pressure Support and BIPAP from Advantage.

For use of the ventilation device according to the invention in anesthesia is the outlet line as a breathing circuit with one inhalation line and one Inhalation valve and an exhalation line executed with an exhalation valve. To prepare the breathing gas exhaled by the patient is either on the outgoing line, or in the exhalation line, or but in the return line, a carbon dioxide absorber is arranged.

To generate an anesthetic gas mixture is in addition to the Another source of nitrous oxide actuated by the control unit intended. The oxygen source and the nitrous oxide source work as Gas mixer to over a predetermined oxygen-nitrous oxide ratio an anesthetic evaporator to the through the inlet line To discharge the outlet line and the return line formed circuit. The oxygen laughing gas is removed by means of the anesthetic evaporator Mixture supplied a predetermined amount of anesthetic vapor.

An embodiment of the invention is shown in the drawing and explained in more detail below.  

Show it:

Fig. 1 shows a first respiratory device,

Fig. 2 shows a second breathing device,

Fig. 3 shows a third breathing device,

Fig. 4 shows a fourth ventilation device.

Fig. 1 shows schematically a first respiratory device 1 in which means of a conveying device 2 via an input line 3 and a buffer volume sucked 4 air from the environment 5 and an outlet line 6 to a patient 8 is supplied. From the outlet line 6, a discharge opening 9 branches off which is connected in terms of flow via a return line 11 to the buffer volume. 4 An adjustable valve 10 is arranged both in the outlet line 6 and in the return line 11 , which can be actuated via a valve setting element 101 in such a way that the flow resistance in the return line 11 is correspondingly increased when the cross-section in the outlet line 6 is reduced. An oxygen source 12 , which is actuated by a control unit 13 , is connected to the buffer volume 4 . A flow sensor 7 and an oxygen sensor 14 are arranged in the line of the outflow line 6 downstream of the outflow opening 9 and deliver a first measurement signal proportional to the gas flow or a second measurement signal proportional to the oxygen concentration to the control unit 13 via a first line 15 and a second line 16 . The gas flow is set on the delivery device 2 with a first setpoint adjuster 17 and the desired oxygen concentration is set on the control unit 13 with a second setpoint adjuster 18 . The gas exhaled by the patient 8 reaches the environment 5 via an expiration line 19 and an expiration valve 20 which can be controlled by the control unit 13 .

The method of operation of the first ventilation device 1 according to the invention is as follows:
With the first setpoint adjuster 17 , the maximum gas flow required by the patient is set on the conveying device 2 . For this purpose, the conveying device sucks in air from the environment 5 via the inlet line 3 and the buffer volume 4 and pumps the gas into the outlet line 6 .

The oxygen concentration desired for ventilation is entered into the control unit 13 using the second setpoint adjuster 18 . The control unit 13 is also connected to the valve 10 via the valve setting element 101 in order to set the gas flow to the patient 8 as a function of a flow profile stored in the control unit 13 . The actual value of the gas flow is measured with the flow sensor 7 and compared in the control unit 13 with the specified flow profile. In the event of deviations, the valve 10 in the outlet line 6 is either opened or closed further, while the valve 10 in the return line 11 is actuated in the opposite direction to that in the outlet line 6 , so that the gas flow in the return line 11 is reduced when the gas flow to the patient 8 is increased is. In the inspiration phase, the expiration valve 20 is closed or set to a maximum inspiration pressure. At the end of inspiration, the gas flow is interrupted in the outlet line 6 with the valve 10, the expiration valve 20 is switched by the control unit 13 in the open position and the patient 8 can exhale. During the expiration phase, the valve 10 in the return line 11 is completely open, so that the gas sucked in by the conveying device 2 from the buffer volume 4 flows back into the buffer volume 4 in the circuit.

The control of the oxygen supply is carried out so that during the inspiration phase, depending on the gas flow determined with the flow sensor 7 , a metering valve (not shown in FIG. 1) within the oxygen source 12 is actuated and the oxygen is mixed in proportion to the measured gas flow into the ambient air. The oxygen concentration is monitored by the oxygen sensor 14 and the measured concentration value is displayed on the control unit 13 . The measured value supplied by the oxygen sensor 14 can, however, also be included in the setting of the oxygen concentration by presetting the dosage via the flow measurement with the flow sensor 7 and fine adjustment by measuring the oxygen concentration with the oxygen sensor 14 . Cascade-like control loops are particularly suitable for setting the oxygen concentration.

FIG. 2 schematically illustrates a second ventilation device 100 in which the valve 10 has been replaced by a diaphragm valve 22 in the outlet line 6 as a significant change compared to the first ventilation device 1 , FIG. 1. The same components are provided with the same reference numbers in FIG. 1.

While flow-controlled ventilation was implemented with the first ventilation device 1 , the second ventilation device 100 is preferably used to carry out pressure-controlled ventilation. The membrane valve 22 consists of a membrane chamber 24 which is closed off by a membrane 23 and into which the outflow opening 9 and the return line 11 open. The outflow opening 9 can be closed with the membrane 23 , which is actuated by a linear drive 25 connected to the control unit 13 . When the membrane valve 22 is open, there is a gas connection between the outflow opening 9 and the return line 11 .

A pressure setpoint value is entered into the control unit 13 with a pressure setpoint adjuster 171 to carry out the pressure-controlled ventilation. The membrane 23 is pressed by the linear drive 25 against the outflow opening 9 with a predetermined force. This force results from the pressure setpoint and the cross-sectional area of the outflow opening 9 . If the pressure in the outflow opening 9 drops below the pressure setpoint, the diaphragm valve 22 closes more strongly and conducts more gas into the outflow line 6 . If, on the other hand, the pressure in the outflow opening 9 rises above the pressure setpoint, the diaphragm valve 22 opens more strongly and conducts more gas into the return line 11 . The gas escaping via the outflow opening 9 flows back into the buffer volume 4 via the return line 11 . To compensate for possible pressure fluctuations, the pressure in the outlet line 6 behind the diaphragm valve 22 can additionally be measured with a pressure sensor 21 during the inspiration phase and the measured value within the control unit 13 can be included in the calculation of the predetermined force for the linear drive 25 . The expiration valve 20 is closed during the inspiration phase and is opened by the control unit 13 at the beginning of the expiration. At the same time, the diaphragm valve 22 is completely opened at the beginning of the expiration in order to interrupt the gas flow to the patient 8 . The gas supplied by the conveying device 2 is then passed directly from the outflow opening 9 via the membrane chamber 24 and the return line 11 into the buffer volume 4 . A check valve 60 prevents the gas from flowing back into the conveying device 2 during expiration. The control unit 13 contains a timer, not shown in the figures, with which the inspiration and expiration phases are set. The expiration valve 20 is illustrated in FIGS . 1 and 2 as a valve which can be actuated electrically by the control unit 13 . Alternatively, there is the possibility of pneumatically actuating the expiration valve via the pressure building up in the outflow line during the inhalation phase and closing it during the inhalation phase. This, referred to as self-control valve control, is, for. B. described in DE 41 42 295 C2 using the example of a pneumatically controllable supply valve.

FIG. 3 schematically shows a third ventilation device 200 , in which, as an essential change compared to the second ventilation device 100 , FIG. 2, the outlet line 6 is designed as a breathing circuit with an inhalation line 61 and an inhalation valve 62 and an exhalation line 63 with an exhalation valve 64 . Such an arrangement is suitable for performing inhalation anesthesia.

The same components are designated with the same reference numerals in FIG. 2. A carbon dioxide absorber 111 is arranged in the return line 11 in order to process the breathing gas, in particular to remove carbon dioxide. The inlet line 3 leaving the buffer volume 4 is closed off to the environment 5 by a pressure relief valve 31 and a vacuum valve 32 . In addition to oxygen, laughing gas 121 is metered into the buffer volume 4 by means of a laughing gas source 121 that can be actuated by the control unit 13 . The sources 12 , 121 work as a gas mixer with a concentration ratio of laughing gas and oxygen predetermined by the control unit 13 . If there is a lack of gas in the buffer volume 4 , air can be drawn in from the environment 5 via the vacuum valve 32 , and excess gas can escape through the pressure valve 31 . The nitrous oxide / gas mixture is passed through an anesthetic evaporator 122 and enriched with anesthetic vapor in a known manner.

To carry out an inspiration stroke, the outflow opening 9 is closed with the membrane 23 , and the gas drawn in by the conveying device 2 from the buffer volume 4 reaches the patient 8 via the inhalation line 61 . During the expiration, the outflow opening 9 is opened through the membrane 23 , and the gas exhaled by the patient 8 via the exhalation line 63 flows through the outflow opening 9 , the return line 11 , the carbon dioxide absorber 111 into the buffer volume 4 . The buffer volume 4 is expediently designed as an elastic bellows and should be dimensioned such that at least the gas volume of a maximum breath can be stored in it.

In FIG. 4, a fourth, suitable for carrying out an inhalation anesthetic ventilation device 300 is schematically illustrated, in which, as a substantial change from the third ventilation device 200 of FIG. 3, the exhaled by the patient 8 gas via the expiratory line 19 in the buffer volume 4 flows back. The same components are designated with the same reference numerals in FIG. 3. With the check valve 60 , a backflow of the breathing gas into the membrane valve 22 or the delivery device 2 is to be prevented during expiration.

Claims (15)

1. Ventilation device with a conveying device (2), which respiratory gas sucks via an input line (3) and pumped into a disposal pipe (6), with a branching off from the discharge line (6) discharge opening (9) through which a with a discharge valve (10 ) adjustable partial flow of the conveyed gas escapes and with at least one oxygen source ( 12 ) that can be connected to the ventilation device, characterized in that a gas flow from the outflow opening ( 9 ) to the inlet line ( 3 ) flows from the outlet opening ( 9 ) to the inlet line ( 3 ) enabling return line ( 11 ) is present and that the oxygen source ( 12 ) upstream of the outflow opening is connected to the circuit formed by the inlet line ( 3 ), the outlet line ( 6 ) and the return line ( 11 ). 2. Ventilation device according to claim 1, characterized in that a buffer volume ( 4 ) is present in the line of the input line ( 3 ). 3. Ventilation device according to claim 2, characterized in that the return line ( 11 ) and / or the oxygen source ( 12 ) are connected to the buffer volume ( 4 ). 4. Ventilation device according to one of claims 1 to 3, characterized in that a control unit ( 13 ) actuating the oxygen source ( 12 ) is provided. 5. Ventilation device according to one of claims 1 to 4, characterized in that a flow meter ( 7 ) is present downstream of the outflow opening ( 9 ). 6. Ventilation device according to claim 5, characterized in that the flow meter ( 7 ) is connected to the control unit ( 13 ) and delivers a first measurement signal for influencing the oxygen source ( 12 ). 7. Ventilation device according to one of claims 4 to 6, characterized in that an oxygen sensor ( 14 ) is present in the line of the outgoing line ( 6 ), which is connected to the control unit ( 13 ) and provides a second measurement signal for influencing the oxygen source ( 12 ) . 8. Ventilation device according to one of claims 1 to 7, characterized in that the conveying device is a turbine drive ( 2 ). 9. Ventilation apparatus of claims 1 to 8, characterized in that the outlet valve is designed as a gas flow from the discharge opening (9) which influences the diaphragm valve (22) according to one. 10. Ventilation device according to one of claims 1 to 9, characterized in that the outlet line is designed as a breathing circuit with an inhalation line ( 61 ) and an inhalation valve ( 62 ) and an exhalation line ( 63 ) with an exhalation valve ( 64 ). 11. Ventilation device according to claim 10, characterized in that a carbon dioxide absorber ( 111 ) is arranged in the line of the outgoing line ( 6 ) and / or the exhalation line ( 63 ) and / or the return line ( 11 ). 12. Ventilation device according to one of claims 4 to 11, characterized in that in addition to the oxygen source ( 12 ) a controllable laughing gas source ( 121 ) is present. 13. Ventilation device according to claim 12, characterized in that the oxygen source ( 12 ) and the laughing gas source ( 121 ) are designed as a gas mixer for delivering a predetermined laughing gas-oxygen ratio, and that downstream of the oxygen source ( 12 ) and / or the laughing gas source ( 121 ) an anesthetic evaporator ( 122 ) is provided. 14. Ventilation device according to one of claims 2 to 13, characterized in that the buffer volume ( 4 ) is designed as an elastic bag. 15. Ventilation device according to one of claims 10 to 14, characterized in that the exhalation line is connected as an expiration line ( 19 ) with the buffer volume ( 4 ) and / or the input line ( 3 ).