DE102008017339A1 - Gas e.g. oxygen, supplying device for use during e.g. non-invasive breathing of spontaneously breathing patient in hospital, has control unit controlling flowrate regulating unit based determined flow rate - Google Patents

Abstract

The device has a flowrate regulating unit (D) regulating flowrate of gases supplied to a patient (P) via inhalation branches (1, 2). A flow detector (F) is arranged in exhalation branches (3-5). A control unit (S) controls the regulating unit based on determined flow rate. An exhalation valve (E) i.e. passive diaphragm-operated valve, is arranged in the exhalation branches, where airway pressure preset by the control unit is pneumatically transferred to a membrane of the valve. A pressure measuring device (A) is arranged in the inhalation branches.

Description

The The invention relates to a device for supplying a spontaneously breathing Patients with a gas, having an inhalation branch, an exhalation branch and means for regulating the flow rate of the patient over the Inhalationszweig fed Gas.

Under the term "gas" below to understand gases and gas mixtures.

Generic device to supply a spontaneous breathing patient with a gas For example, in the noninvasive ventilation of spontaneously breathing patients using the CPAP method (Continuous Positive Airway Pressure) for use. This is usually a constant gas flow realized. The flow is adjusted so that the necessary support print while the inhalation and the exhalation phase is achieved. Usually the supply takes place of the gas to the patient by means of a nasal mask, preferably by means of a face mask. Furthermore, generic devices used in intubated patients.

During the Inhalation phase, however, the gas supplied to the patient is not entirely by the Patients inhaled. That to the patient during the exhalation phase supplied Gas becomes complete unused - mixed with the exhaled by the patient gas - discharged and usually to the environment issued.

It It is obvious that the procedure described above for The consequence is that considerable quantities of gas remain unused. Will that be supplied to the patient Gas taken from a central gas supply, such as in hospitals in the Trap of air and oxygen usually the case is so causes the procedure described above due to the increased, unwanted gas consumption only small additional costs. In case of special and / or high quality Gases - exemplified be helium / oxygen mixtures - leads the procedure described above too unnecessary high additional costs. Is the gas supplied to the patient in compressed gas cylinders delivered, will about it addition, a more common Bottle change required.

task The present invention is a generic device to indicate with a gas for supplying a spontaneously breathing patient which avoids the disadvantages described above.

to solution This object is a device for supplying a spontaneously breathing Patients with a gas suggested that characterized is that the exhalation branch means for detecting the flow rate and has and by means of a control unit or control in dependence from the determined flow rate, the means for controlling the flow rate of the patient fed the inhalation branch Gas are controlled.

through the device according to the invention for Supplying a spontaneously breathing patient with a gas is now the gas consumption during the inhalation as well the exhalation phase of the patient by a needs-based control the metered amount of gas reduced. Basically, that is the flow rate of the patient during the inhalation and exhalation phase supplied gas is reduced, if a flow is detected in the exhalation branch - in this case is yes a gas surplus in front. In this case, the amount of gas supplied is usually only up to an adjustable or preconfigured flow value, the only in exceptional cases Zero is reduced in the exhalation branch. Is in Exhalationszweig No or only a small flow is determined, the flow rate of the patient during the inhalation and exhalation phase supplied gas increases.

The inventive device for supplying a spontaneously breathing patient with a gas using the proven and accepted patient interfaces, like face mask, especially nasal masks, etc. as well as intubated Patients are realized.

• – in dem Exhalationszweig wenigstens ein Exhalationsventil angeordnet ist und dem Exhalationsventil von der Steuereinheit bzw. Steuerung ein Atemwegsdruck vorgebbar ist,
• – das Exhalationsventil ein passives, membrangesteuertes Ventil ist, bei dem der von der Steuereinheit bzw. Steuerung vorgegebene Atemwegsdruck vorzugsweise pneumatisch auf die Membran des Ventils übertragen wird,
• – in dem Exhalationszweig wenigstens eine Durchflussmessvorrichtung angeordnet ist,
• – in dem Inhalationszweig wenigstens eine Druckmessvorrichtung angeordnet ist,
• – dem Inhalationszweig eine Vorrichtung zum Vermischen eines oder wenigstens zweier, dem Patienten zuzuführender Gase zugeordnet ist und
• – dem Exhalationszweig eine Vorrichtung zum Aufbereiten des über den Exhalationszweig abgeführten Gases zugeordnet ist.

Further advantageous embodiments of the device according to the invention for supplying a spontaneously breathing patient with a gas, which are the subject of the dependent claims, are characterized in that

• In the exhalation branch at least one exhalation valve is arranged and the exhalation valve of the control unit or control an airway pressure can be predetermined,
• The exhalation valve is a passive, diaphragm-controlled valve, in which the airway pressure predetermined by the control unit or control is preferably transmitted pneumatically to the diaphragm of the valve,
• In which exhalation branch at least one flow measuring device is arranged,
• In the inhalation branch at least one pressure measuring device is arranged,
• - The inhalation branch is associated with a device for mixing one or at least two, the patient to be supplied gases and
• - The exhalation branch is associated with a device for processing the discharged via the Exhalationszweig gas.

The inventive device to treat a spontaneously breathing patient with a gas as well Further refinement thereof will be described below with reference to FIG the figure illustrated embodiment explained in more detail.

The device shown in the figure for supplying a spontaneously breathing patient with a gas has an inhalation branch consisting of the line sections 1 and 2 , and a Exhalationszweig, consisting of the line sections 3 . 4 and 5 , on.

The the patient P to be supplied Gas is provided by means of a gas supply unit V. at this gas supply unit V can be a central gas supply, as in hospitals, for example is present to a compressed gas cylinder or a bottle bundle, a LPG tank, etc. act.

Become the patient P two or more gases, possibly with a time changeable Mixing ratio, supplied can according to an advantageous embodiment of the device according to the invention the gas supply unit V is a device for mixing at least two, the patient P to be supplied Include gases.

The inhalation branch has means for regulating the flow rate D of the patient via the inhalation branch ( 1 . 2 ) supplied gas. Also provided are means for detecting the flow rate F in the exhalation branch ( 3 . 4 . 5 ), an exhalation valve E and a control unit S. The latter is via the dashed data lines 6 . 7 and 8th connected to the aforementioned components.

According to the invention, a pressure preset for the positive airway pressure is now set. The set pressure is from the control unit S via the data line 7 passed as pressure specification to the exhalation valve E. The exhalation valve E thus closes the Exhalationszweig when the predetermined pressure is not reached and opens the Exhalationszweig as soon as the predetermined pressure is exceeded.

Corresponding an advantageous embodiment of the device according to the invention the exhalation valve E is a passive, membrane-controlled valve, in which the predetermined by the control unit S airway pressure pneumatically transferred to the diaphragm of the valve. This exhalation valve E can also be directly on the face or respiratory mask of the patient P be connected.

The data acquired by the means for detecting the flow rate F - the data is usually recorded by means of a so-called flow detector - are transmitted via the data line 8th given to the control unit S. This can thereby detect whether the flow in the Exhalationszweig is less than a preset or adjustable threshold. If the control unit S detects that this threshold value is undershot, the data line is used 6 the flow control unit D is controlled such that the patient P via the line sections 1 and 2 Gas from the gas supply unit V is supplied.

U. It makes sense if the flow control unit D at any time allows a minimal gas flow to the patient P. It makes sense to provide the flow control unit D at any time at least that flow over the inhalation branch, the as minimum flow from the flow detector in the exhalation branch is expected. According to a possible variant delivers the Flow control unit D at all times a minimum flow, which is bigger as the flow threshold of the flow detector. The advantage of a Such procedure is to be seen in that during the Exhalation phase of the patient in the inhalation branch further metered becomes. In principle, could The control unit interrupt the dosing, as in Exhalationszweig anyway a gas flow above the threshold is present. In order to can in practical application typically delay times - in the case a necessary dosing start - shortened and safety-related Aspects, such as rinsing in case of leaks in the inhalation branch.

So long the exhalation valve E predetermined pressure Exhalationszweig is not reached, the exhalation valve E remains closed. Will the patient P over the inhalation branch supplies more gas than the patient needs P builds there is a positive pressure at the interface P and breathing mask, in the figure of clarity half is not shown on.

If now the pressure specified in the exhalation branch is exceeded, the exhalation valve E opens the exhalation branch and excess gas flows out via the exhalation branch and the flow detector F arranged therein. This outflow of the gas detected by means of the flow detector F has the consequence that the control unit S controls the flow control unit D in such a way that it controls the gas flow in the line sections 1 and 2 reduced.

This reduction takes place until the patient P again inhales more gas than is currently provided via the inhalation branch. As a result, the pressure on the breathing mask decreases or in the Exhalationszweig very quickly, which has the consequence that the exhalation valve E closes when it falls below the predetermined pressure. Then, the control unit S recognizes by means of the flow detector F again that there is no more gas flow, and accordingly releases the gas flow in the inhalation branch.

The Control unit or control S required by the flow detector F merely the information as to whether a certain flow - near zero - has been exceeded. Therefore this capture a low accuracy is sufficient, no need (High) precision Flow sensors are used. This represents a substantial Cost advantage, since the flow detectors used designed as disposable devices could be, which makes a sterilization of these devices superfluous.

The The procedure described above works independently of the amount of gas inhaled by the patient. Furthermore it is irrelevant whether the gas is inhaled by the patient or via a Leakage of the management system escapes, since in all cases the Pressure is kept constant.

The inventive device to educate a spontaneously breathing patient with a gas it is suggested that at least one inhalation branch in the inhalation branch Pressure measuring device A, which is shown in dashed lines in the figure is shown, is arranged. This allows a measurement of the pressure in the inhalation branch or directly on the patient P or respiratory mask. The thus determined pressure value can via the control unit or control S the correction of the exhalation valve E predetermined pressure serve. Furthermore, a measurement of the pressure in Exhalationszweig and in this case preferably close to the patient P feasible.

The The procedure described above is also suitable for an application in the so-called bi-level positive airway pressure ventilation. At this will be the Exhalationsventil E predetermined control pressures.

The inventive device to educate a spontaneously breathing patient with a gas It is proposed that the Exhalationszweig a device for Processing the over removed the Exhalationszweig Gas is assigned. This advantageous embodiment results, for example. then sense, if that's over removed the Exhalationszweig Gas at least partially recycled or from the gas at least a component should be separated and recycled.

• – die im Exhalationszweig verwendeten Komponenten Exhalationsventil und Flow-Detektor können als Wegwerfgeräte ausgelegt werden, da sie nicht hochpräzise arbeiten müssen; damit entfällt auch die Notwendigkeit einer aufwendigen Sterilisation
• – Verwendung herkömmlicher und akzeptierter Atemmasken möglich
• – Höhere Einatmungsspitzen des Patienten können ausgeglichen werden
• – Undichtheiten des Systems bzw. der Leitungen werden ausgeglichen und führen lediglich zu einem erhöhten Gaseverbrauch
• – Undichtheiten des Systems bzw. der Leitungen können durch die Steuerung erkannt und ggf. dem Anwender mitgeteilt werden
• – keine aufwendige Erkennung der Patientenatmung (Inhalation/Exhalation) erforderlich, da Funktionsweise in beiden Atemphasen identisch

The device according to the invention for supplying a spontaneously breathing patient with a gas has a number of advantages over the prior art, which are listed below in the following manner:

• - The exhalation valve and flow detector components used in the exhalation branch can be designed as disposable devices because they do not have to operate with high precision; This eliminates the need for expensive sterilization
• - Use of conventional and accepted breathing masks possible
• - Higher inspiratory tips of the patient can be compensated
• - Leakage of the system or the lines are compensated and only lead to increased gas consumption
• - Leaks in the system or lines can be detected by the controller and, if necessary, communicated to the user
• - no elaborate detection of patient breathing (inhalation / exhalation) is required because the functioning is identical in both breathing phases

Claims (7)

Apparatus for supplying a spontaneously breathing patient with a gas, comprising an inhalation branch, an exhalation branch and means for regulating the flow rate of the gas supplied to the patient via the inhalation branch, characterized in that the exhalation branch ( 3 . 4 . 5 ) Means for detecting the flow rate (F) and by means of a control unit (S) in dependence on the determined flow rate, the means for regulating the flow rate (D) of the patient via the inhalation branch ( 1 . 2 ) are supplied to the supplied gas. Device according to claim 1, characterized in that in the exhalation branch ( 3 . 4 . 5 ) at least one exhalation valve (E) is arranged and the exhalation valve (E) of the control unit (S) an airway pressure can be predetermined. Device according to claim 2, characterized in that that the exhalation valve (E) is a passive, membrane-controlled Valve is at which the airway pressure preset by the control unit (S) preferably pneumatically transferred to the diaphragm of the valve becomes. Device according to one of the preceding claims 1 to 3, characterized in that in the Exhalationszweig ( 3 . 4 . 5 ) at least one flow measuring device (F) is arranged. Device according to one of the preceding claims 1 to 4, characterized in that in the inhalation branch ( 1 . 2 ) at least one pressure measuring device (A) is arranged. Device according to one of the preceding claims 1 to 5, characterized in that the inhalation branch ( 1 . 2 ) is associated with a device for mixing at least two, the patient (P) to be supplied gases. Device according to one of the preceding claims 1 to 6, characterized in that the exhalation branch ( 3 . 4 . 5 ) a device for processing the via the Exhalationszweig ( 3 . 4 . 5 ) associated gas is assigned.