DE4105228A1 - Operating anaesthetic vaporiser for low boiling point narcotics - using control unit to cool vaporising chamber so that internal pressure drops below that in narcotic gas duct - Google Patents

Abstract

In the null setting the vapouriser is bridged by a diversion path so that fresh gas can be fed directly into the anaesthesing appts. to bring the internal pressure of the vapourising chamber (7) below that pertaining in the narcotic gas duct (15), the chamber is cooled down and then a connection is made between the narcotic gas duct or the surroundings and the vapourising chamber via a switching element (21). The switching element (20) at the by-pass (5) is then opened. The switching element (21) at the junction (14) is connectable to the surroundings via ventilation sockets. A control unit (25) has a signal processor (26) connected to a differential pressure pick-up (28) for processing a pressure signal from an internal pressure sensor (24) in the vapourising chamber. ADVANTAGE - Prevents increased delivery of narcotic gas to fresh gas at initiation of vapouriser.

Description

The invention relates to an anesthetic evaporator with an evaporator chamber into which one Fresh gas line opens, from which one Carrier gas line for enrichment with evaporated Anesthetic gas branches into the evaporator chamber, the Flow through a metering device is adjustable, and which is downstream downstream the evaporator chamber with that on the evaporator chamber Fresh gas line bypassed in bypass an anesthetic gas line combined, with at a locking device interrupted Flow through the evaporator chamber Fresh gas line through at the branch and switching elements arranged along the union a bypass route is led.

A well-known anesthetic evaporator after the DE-A 12 71 903 uses such an arrangement to along the carrier gas soaked with anesthetic Wicks and, via the dosing device directed to add fresh gas and after union both gas flows as anesthetic gas to a consumer, e.g. B. to provide an anesthetic gas device. When the evaporator chamber is closed Ready state a certain vapor pressure above the  Anesthetic liquid in the evaporator chamber, the u. a. from the prevailing evaporator temperature is dependent. The resulting anesthetic vapor is given to the outside via a ventilation line. A however, such ventilation is not suitable if Anesthetics are used at low Boil temperatures, e.g. room temperature. This can mean that the boiling point continues increasing ambient or evaporator temperatures form such a high vapor pressure that over the Vent line constantly to the anesthetic gas Environment is derived. This would become one incompatible and undesirable enrichment of the Lead ambient air with anesthetics.

Conventional anesthetic vaporizers, like them currently used on the market to avoid any leakage from evaporating anesthetic to the environment Shut-off device, which the evaporator in its Stand by at both the inlet for the Fresh gas as well as at the outlet for the anesthetic gas operate a switching element such that the Junction and the union of the fresh gas line gas-tight from or to the carrier gas line is complete, then the fresh gas line over a bypass route at the evaporator chamber is guided past (Instructions for use: Dräger-Vapor Anesthetic evaporator, No. GA 5327.0 d / e, 13. Edition, November 1988). To start up the known evaporator is the locked Locked position released and the fresh gas line with the carrier gas line connected, as well as the Bypass line blocked off. Has, however, during  a standby time of the evaporator in the Evaporator chamber because of the low boiling Anesthetic to an increased vapor pressure Anesthetic gas is developed the first time it is opened the evaporator into its operating position Initial surge ("bolus") of approximately 100% Anesthetic gas to the connected anesthetic machine given for forwarding to the patient. Also the initially only with anesthetic-free fresh gas filled lines are saturated with anesthetic gas on, so that initially instead of pure fresh gas carrier gas saturated with anesthetic into the Bypass guide and the carrier gas line flows. If this initial surge can also be small in terms of quantity may like, the associated initial high anesthetic concentration in the anesthetic gas too lead to undesirable side effects. In particular, when using modern, highly effective anesthetic on exact adherence to set anesthetic concentration be what's even more important if so-called anesthetic circulation systems for the closed anesthesia can be used. In these is only so much anesthetic in the evaporator Add carrier gas as determined by the consumer (the Patient) has been removed from the breathing circuit.

The present invention is therefore the object based on an anesthetic evaporator of the above Art to improve so that especially when using low-boiling anesthetics an increased release of Anesthetic gas to the fresh gas at start-up of the anesthetic evaporator is prevented.

The problem is solved in that before Release of the flow through the evaporator chamber  Interior space is brought to such an internal pressure, that he is below that in the anesthetic gas line prevailing line pressure, which is initially the switching element located at the union and then the switching element located on the junction is opened.

The main advantage of the invention is that that by reducing the pressure within the Evaporator chamber during standby possibly generated gas volume of the above liquid anesthetic gas is reduced to the extent that when opening the Switching element at the union first a Vacuum equalizing volume of fresh gas in the Evaporator chamber and passed into the fresh gas line until the pressure drop between the anesthetic gas line and evaporator chamber is balanced. That from the Anesthetic gas line suctioned gas volume is typically 10 to 100 ml. This aspirated Volume is in its gas type composition in the Usually pure fresh gas, because during the Standby time or zeroing the Dosing device on the anesthetic evaporator Fresh gas via the detour route directly into the Anesthetic gas line is guided. Only after the Pressure equalization between the anesthetic gas line and Evaporator chamber is made, it will Switching element opened at the junction and the Flow through the bypass blocked, so that Fresh gas via the carrier gas line now through the Evaporator chamber can be directed. The Bypass route is now interrupted and the Dosage of the desired anesthetic in the Fresh gas line can on the metering device can be set.  

However, the switching element can also expediently through a ventilation connection with the environment in Will be connected as soon as it is released Flow through the evaporator chamber is actuated.

It may be convenient to the switching element on the Association by one with the locking device coupled and operable by unlocking it Line valve in a short circuit line between the Training association and the anesthetic gas line. This arrangement opens up the possibility of Unlocking the locking device at the same time to ventilate the interior of the evaporator chamber, after which blocked the bypass route in a known manner and the junction and the union between the Fresh gas line and the carrier gas line at the same time can be produced.

A suitable cooling device for generating the Internal pressure in the evaporator chamber only needs to be placed on the wall. Before commissioning of the anesthetic evaporator is the cooling device turn on until the internal pressure in the Evaporator chamber was reduced accordingly. To The evaporator chamber can be ventilated Cooling device can be switched off again, or it can even put a heater into operation be in the same place as that Cooling device is applied to the evaporator chamber the anesthetic to the necessary Operating temperature. In this Context, it is advantageous as a cooling device To provide Peltier coolers, which if necessary also as a heater for heating the Evaporator chamber to the necessary operating temperature can be used.  

An easy way to reduce the Internal pressure in the evaporator chamber consists of to attach a suction nozzle to a vacuum pump. The aspirated amount of anesthetic can over a suitable Anesthetic conduction in appropriate activated carbon filters be caught, so that pollution of the environment with anesthetic vapor is excluded.

A device for wiring a Anesthetic evaporator to carry out the mentioned method is that a Control unit is provided, the one Signal processing part, which for Processing a pressure signal from a pressure sensor in the evaporator chamber and from a pressure sensor in the anesthetic gas line or the surrounding area with a Differential pressure sensor is connected, and that the Control unit is equipped with a control part, the one with the negative pressure in the Evaporating chamber generating device and on the other hand with the switching elements on the junction and connected to the association.

The control unit recognizes the closed one State of the switching elements on the junction and on the union so that it is made for the pressure signals the interior of the evaporator chamber on the one hand and the Anesthetic gas line or the environment on the other hand is sensitive. Because of the missing Pressure difference, measured according to the Individual signals from the pressure sensors are generated by the Signal processing part for a control signal Actuation of the cooling device, whereupon the interior the evaporator chamber is cooled until the  Internal pressure of the evaporator chamber a predetermined Difference to the pressure in the anesthetic gas line or in the surrounding area. At this time first the switching element at the union opened that a limited volume of gas from the Flow the anesthetic gas line into the evaporator chamber lets so that there is pressure equalization between the Interior of the evaporator chamber and the Anesthetic gas line comes, which also the switching element is opened at the junction so that fresh gas can flow through the evaporator chamber.

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

Show it

Fig. 1 is a Narkosemittelverdunster in section with a wiring and a control unit,

Fig. 2 is a circuit diagram for an anesthetic evaporator with control unit.

In an anesthetic evaporator ( 1 ) from a fresh gas source ( 2 ) via an fresh gas line ( 3 ) an oxygen-air mixture is introduced as fresh gas, which is to be enriched with an anesthetic ( 4 ) ( Fig. 1). At the entrance of the anesthetic vaporiser (1) is a branch (5) is guided past on the one hand the fresh containing gas in the bypass guide (6) at a the anesthetic (4) Verdunsterkammer (7), and on the other hand, the fresh gas via a carrier gas line (8) is passed into the evaporator chamber ( 7 ). The direction of flow of the fresh gas is indicated by solid arrows. The liquid anesthetic ( 4 ) evaporates in the interior of the evaporator chamber ( 7 ) with the support of a wick ( 9 ) which lines the inner wall of the evaporator chamber ( 7 ) and is soaked with the anesthetic ( 4 ). The carrier gas from the carrier gas line ( 8 ) saturates with the anesthetic ( 4 ) and escapes from the evaporator chamber via an outflow line ( 10 ) to a metering device which consists of a metering cone ( 11 ) in a metering cone ( 12 ). By adjusting the gap between cone ( 11 ) and cone ( 12 ) by means of a handwheel ( 13 ), the ratio between anesthetic gas-free fresh gas in the bypass duct ( 6 ) and the carrier gas saturated with the anesthetic ( 4 ) is set and thus the anesthetic gas concentration in the combination ( 14 ) determined between carrier gas and fresh gas. The anesthetic gas generated in this way is passed on to an anesthetic machine ( 16 ) via an anesthetic gas line ( 15 ). The direction of flow of the carrier gas saturated with anesthetic ( 4 ) is represented by directional arrows which are provided with a filled point which is intended to symbolize the anesthetic ( 4 ). On the handwheel ( 13 ) there is a lock ( 17 ) which can be operated by a lock button ( 18 ) when the anesthetic evaporator ( 1 ) is to be brought into the so-called zero position, in which the gap between the cone ( 11 ) and the cone ( 12 ) sealed and this locking position is fixed by the locking pin ( 19 ). In the operating mode shown in Fig. 1, the lock ( 17 ) is not effective. In the fresh gas line ( 3 ) in the flow direction before the branch ( 5 ) and in the anesthetic gas line ( 15 ) in the flow direction after the union ( 14 ) there is a switching element ( 20 , 21 ) designed as a 3/2-way valve, each one connect the bypass route ( 22 ) bridging the bypass guide ( 6 ). The outer periphery of the evaporator chamber ( 7 ) is surrounded by a cooling device ( 23 ) and its interior is provided with an interior pressure sensor ( 24 ). A control unit ( 25 ) receives in its signal processing unit ( 26 ) the pressure signals both from the interior pressure sensor ( 24 ) and from an anesthetic gas pressure sensor ( 27 ) in the anesthetic gas line ( 15 ) via a differential pressure transmitter ( 28 ). The switching elements ( 20 , 21 ) and the cooling device ( 23 ) are connected to a control part ( 29 ) of the control unit ( 25 ). From the control part ( 29 ) the switching elements ( 20 , 21 ) and the cooling device ( 23 ) also receive the electrical energy necessary for their actuation or operation.

In the operating state shown in FIG. 1, fresh gas flows through the fresh gas line into the bypass guide ( 6 ) and into the carrier gas line ( 8 ), whereupon in the union ( 14 ) anesthetic gas is led into the anesthetic gas line ( 15 ) to the anesthetic machine ( 16 ). The bypass route ( 22 ) is blocked by the switching elements ( 20 , 21 ). If the anesthetic supply is to be interrupted or switched off, the fresh gas line ( 3 ) and the anesthetic gas line ( 15 ) are separated from the bypass duct ( 6 ) via the switching elements ( 20 , 21 ) in accordance with a switching command from the control part ( 29 ) and the line branch to the bypass route ( 22 ) opened so that the fresh gas via the fresh gas line ( 3 ), bypass section ( 22 ) (indicated by the dashed arrows), anesthetic gas line ( 15 ) is fed directly to the anesthetic machine ( 16 ) without anesthetic ( 4 ) into the Fresh gas was added. Since steam of the anesthetic ( 4 ) accumulates in the evaporator chamber ( 7 ) during this shut-off time, and especially in the case of low-boiling anesthetic ( 4 ), the anesthetic vapor generated in this way can prevail under excess pressure in the evaporator chamber ( 7 ) and the connected conduits, if it were to reopen the switching elements ( 20 , 22 ) an uncontrollable anesthetic gas surge in the anesthetic gas line ( 15 ) to the anesthetic machine ( 16 ), which is avoided by the control unit ( 25 ) first issuing a control command to the control part ( 29 ), whereby the cooling device ( 23 ) is switched on until the interior pressure measured in the evaporator chamber ( 7 ) by the interior pressure sensor ( 24 ) is below a predetermined difference to the pressure in the anesthetic gas line ( 15 ) determined in the anesthetic gas pressure sensor ( 27 ). If this is the case, the switching element ( 21 ) between the union ( 14 ) and the anesthetic gas line ( 15 ) is first opened, so that a fraction of the gas in the anesthetic gas line ( 15 ) flows into the evaporator chamber ( 7 ) for pressure compensation and at the same time the Rinsing the line in the anesthetic evaporator ( 1 ). At the same time, the bypass section ( 22 ) is separated from the anesthetic gas line ( 15 ). When pressure equalization in the evaporator chamber ( 7 ), which is communicated to the signal processing unit ( 26 ) by the differential pressure transmitter ( 28 ), the control part ( 29 ) also opens the switching element ( 20 ) between the fresh gas line ( 3 ) and the branch ( 5 ), and blocks it Bypass route ( 22 ) from the fresh gas line ( 3 ), so that again the operating state shown in Fig. 1 is established.

In Fig. 2 the Narkosemittelverdunster is connected (1) between the fresh gas line (3) and the anesthetic gas conduit (15), wherein the switching elements (20, 21) are operatively connected to each other so that they can be operated simultaneously by the control unit (25) both . The lock ( 17 ) is shown schematically in the locked state, so that the operating state shown in FIG. 2 corresponds to that in which the bypass section ( 22 ) is connected in flow in FIG. 1, so that fresh gas from the fresh gas line ( 3 ) passes over the bypass section ( 22 ) is led into the anesthetic gas line ( 15 ) to the anesthetic machine ( 16 ). In order to include the anesthetic evaporator ( 1 ) in the line between the fresh gas line ( 3 ) and the anesthetic device ( 16 ), the connection between the anesthetic gas line ( 15 ) and the anesthetic evaporator ( 1 ) is established by actuating the lock ( 17 ) via a short-circuit line ( 30 ). so that the negative pressure generated by the cooling device (23) is offset in the Verdunsterkammer (7) relative to the anesthesia line (15) before the switching elements (20, 22) close the bypass path (22) and in its non-illustrated second switching state, the fresh gas line ( 3 ) with the branch ( 5 ) on the one hand and the anesthetic gas line ( 15 ) with the union ( 14 ) on the other. Only when the lock ( 17 ) has connected the short-circuit line ( 30 ) to the anesthetic gas line ( 15 ) are the switching elements ( 20 , 21 ) switched to their illustrated switching position in the second switching position, not shown, which is provided by a compression spring ( 31 ) as a delay holder is illustrated. In this case, the locking ( 17 ) and the switching elements ( 20 , 21 ) are actuated mechanically, so that the control unit ( 25 ) does not need to actuate the switching elements ( 20 , 21 ). Instead of establishing the connection between the anesthetic vaporizer ( 1 ) and the anesthetic line ( 15 ), this can also take place via a ventilation connection ( 33 ) with the surroundings. This alternative is shown in dashed lines.

In another embodiment, not shown, a signal line to the control unit ( 25 ) can be connected to the lock ( 17 ), so that when the lock ( 17 ) is actuated, the control unit ( 25 ) outputs time-delayed signals to the switching elements ( 20 , 21 ) , whereupon the switching element ( 21 ) on the union ( 14 ) and then the switching element ( 20 ) on the branch ( 5 ) is actuated. A mechanical delay coupling between the lock ( 17 ) and the switching element ( 21 ), as shown in FIG. 2 by the compression spring ( 31 ), can then be omitted, as can the mechanical coupling of the switching elements ( 20 , 21 ).

Claims (6)

1.Method for operating an anesthetic evaporator with an evaporator chamber, into which a fresh gas line opens, from which a carrier gas line for enrichment with evaporated anesthetic gas branches off into the evaporator chamber, the flow of which can be adjusted by means of a metering device, and which flows downstream behind the evaporator chamber with the on the evaporation chamber bypasses the fresh gas line bypassed to form an anesthetic gas line, the fresh gas line being guided through a bypass section through switching elements arranged at the branch and at the union when the flow through the evaporator chamber is interrupted, characterized in that before the flow through the evaporator chamber ( 7 ) is released the interior of which is brought to such an internal pressure that it lies below the line pressure prevailing in the anesthetic gas line ( 15 ), after which the one located at the union ( 14 ) he switching element ( 21 ) and then the switching element ( 20 ) located on the branch ( 5 ) is opened. 2. The method according to claim 1, characterized in that the switching element ( 21 ) on the union ( 14 ) by its actuation via a ventilation socket ( 33 ) can be connected to the environment. 3. The method according to claim 1 or 2, characterized in that the switching element ( 21 ) at the union ( 14 ) by a with the locking device ( 17 ) and actuated by its unlocking line valve ( 32 ) in a short-circuit line ( 30 ) between the Association ( 14 ) and the anesthetic gas line ( 15 ) is formed. 4. The method according to any one of claims 1 to 3, characterized in that the internal pressure can be reduced by a cooling device ( 23 ) enveloping the evaporator chamber ( 7 ). 5. The method according to any one of claims 1 to 3, characterized in that the internal pressure by one connected via a suction port Vacuum pump can be reduced. 6. Device for operating an anesthetic vaporizer according to one of the methods of claims 1 to 5, characterized in that a control unit ( 25 ) is provided which has a signal processing part ( 26 ) which for processing a pressure signal from an interior pressure sensor ( 24 ) in the Evaporator chamber ( 7 ) and an anesthetic gas pressure sensor ( 27 ) in the anesthetic gas line ( 15 ) or the environment ( 31 ) is connected to a differential pressure sensor ( 28 ), and which is equipped with a control part ( 29 ) which, on the one hand, has the negative pressure in the evaporator chamber ( 7 ) producing device ( 23 ) and on the other hand with the switching elements ( 20 , 21 ) at the branch ( 5 ) and the union ( 14 ).