DE19605695A1 - Anaesthetic gas extraction conduit - Google Patents

Abstract

The conduit (4) has a pressure sensor (5) in an excess gas outlet (3). This sensor controls a downstream pump (7). There may be a separator (13) for volatile gas and water, with a carbon dioxide and organic substance filter (14) downstream of it, between the sensor and pump. A non return valve (10) with a downstream reservoir (12) may lie between the pump and filter. There may also a be a non return valve (8) to bring in air from the outside, and another non return valve (9) for taking anaesthetic gas to a take-off conduit (15).

Description

The invention relates to an anesthetic gas conduction system for anesthetic machines.

In the entire medical field, patients and staff must before the uncontrolled inhalation of foreign components in the otherwise cleaned indoor air. In particular, the Note anesthetic gases, the exact material composition of each may vary depending on the application.

The anesthetic gas discharges currently used in the clinics work according to the following principle:

A solid gas stream is sucked off through a wall box using negative pressure. The flow volumes per unit of time range between 30 and 90 l / min. Ejectors come either in the wall or in the center Suction units for use, so-called passive systems.

Such an arrangement is described in the patent DE-27 28 723 a central vacuum system is used here. Through the It is therefore appropriate to use a suitable vacuum check valve possible, only the exhaust gases, namely the patient's exhaled air, dissipate.

With the help of such a device, the excess gas is passed on. These are with anesthesia with 3 l / min fresh gas flow about 2.6 l / min, with special Low flow technology about 0.6 l / min.

In terms of quantity, this gas is only a fraction of the total gas flow, which is subtracted. The rest is from the environment, under anesthesia extracted from the operating room, namely up to 90 l / min in total. For this purpose, the known anesthetic gas outlets have openings for Environment.

The disadvantage of the known systems is the following: Is the installation in the wall is not set correctly or the suction power is not sufficient, this can lead to workloads with anesthetic agent (s). By  improper installation on the anesthetic device continues Possibility to create a negative pressure on the breathing system of the anesthetic machine generate, which in turn can interfere with the control of the anesthetic machine.

The object of the present invention is a closed Propose anesthesia gas forwarding to the room load with anesthetic gas to avoid, being an active transport of the to be discharged Patient gas from the breathing system of the anesthetic machine takes place in order to avoid the disadvantages of the prior art.

To solve this problem, an anesthetic gas conduction system with the Features proposed according to claim 1.

The dependent claims contain advantageous refinements the arrangement according to the invention according to claim 1.

A particular advantage of the system according to the invention is that the gases discharged from the anesthetic device, depending on the material Composition of the anesthetic used, specifically treated, pre-cleaned or in a connected recovery plant can be reprocessed.

The practically hardly separable mix of different Gas compositions from various anesthetic applications Discharge via a central suction system according to the state of the art not applicable.

A major advantage of the invention Anesthetic gas delivery system is that only the amount of anesthetic gas is transported away, which escapes as excess gas from the anesthetic machine. The essence of the invention is accordingly that according to claim 1 a pressure-controlled pump for active anesthetic gas transmission is provided. The pump is switched on when an overpressure of for example, specified about 0.5 mbar at the excess gas outlet of the Anesthetic device is present. If the pressure falls below the specified value, for example 0 mbar, the pump is switched off again. The two valves according to Claim 4 are for the accidents "negative pressure" or "positive pressure" on Excess gas outlet of the anesthetic machine provided: They open at a predetermined overpressure of, for example, more than 1.5 mbar or at a vacuum of less than -0.5 mbar.  

According to claims 7 and 8, the invention Anesthetic gas delivery system to an anesthetic gas recovery system, preferably connected for the anesthetic gas xenon. Especially for this application of recycling the anesthetic gas is suitable the system according to the invention is particularly good because, in contrast to State of the art in normal operation no dilution of the Anesthetic gas takes place through sucked-in foreign gas from the environment. The separator and / the filter according to claim 2 are for one Pre-cleaning of the derived gas mixture is provided to a to relieve subsequent recovery plant or also to a To be able to fill the container for anesthetic gas with a suitable purity. The following elements can be combined: water trap or a Dehumidifier, for example in the form of a cooler, with a separator for volatile anesthetic gases, namely in particular halogenated Hydrocarbons, as well as with a CO₂ absorber, a filter for organic substances and / or a microbe filter.

The invention is explained below using an exemplary embodiment with the aid of the single, schematic figure. The anesthetic gas routing system according to the invention connects directly to the excess gas outlet 3 of the breathing system 2 of an anesthetic machine 1 . The actual anesthetic gas outlet 4 with its components consists of anesthetic-resistant materials, which are preferably ceramic, metal, anesthetic-resistant plastics. In a preferred embodiment, all gas-carrying parts can be removed individually, for example for cleaning purposes.

With the help of the pressure-controlled pump 7 , only the amount of excess gas is removed from the anesthetic machine 1 , which escapes there. The pump 7 is switched on when the pressure sensor 5 behind the outlet 3 of the anesthetic device 1 in the anesthetic gas outlet 4 measures an overpressure of, for example, at least 0.5 mbar specified by the control unit 6 . If the pressure falls below, for example, 0 mbar, the pump 7 is switched off again. In the exemplary embodiment, the pump 7 has a maximum delivery rate of 60 l / min. Good experiences have been made with an impeller pump. The check valve 8 for additional air and the check valve 9 for the anesthetic gas discharge line 15 are provided at the outlet 3 for the "underpressure" or "overpressure" malfunctions. Valve 9 opens at an appropriate overpressure of, for example, at least 1.5 mbar, whereas valve 8 opens at an underpressure of less than -0.5 mbar. Through valves 8 and 9 , the anesthetic gas delivery system works without influencing anesthetic machine 1 within a narrow pressure range specified by valves 8 , 9 . The valves 10 , 11 and the buffer volume 12 serve to decouple the anesthetic machine 1 from a downstream unit, preferably an anesthetic gas recovery system. The buffer volume 12 is in particular made of a flexible, reversible material. Reference numeral 13 schematically shows a separator for volatile anesthetic gases and / or for water, and reference numeral 14 represents an absorber and / or one or more filters for CO₂ and for organic metabolic products of the patient in the exhaled anesthetic gas. Such metabolic products are, for example, acetone and methane. By connecting the separator 13 to the anesthetic gas discharge line 15 , the volatile anesthetic gases are derived directly from the anesthetic gas discharge system. In a preferred embodiment, a recovery system for anesthetic gas follows the anesthetic gas routing system behind the check valve 11 . This can be useful for ecological and / or economic reasons, for example when xenon is used as anesthetic gas, which is extremely expensive.

Claims (8)

1. Anesthetic gas conduction system for anesthetic devices, characterized in that in the anesthetic device excess gas outlet ( 3 ) adjoining anesthetic gas conduit ( 4 ) there is a pressure sensor ( 5 ) which is used to control a pump ( 7 ) connected downstream of the pressure sensor ( 5 ). 2. Anesthetic gas conduction system according to claim 1, characterized in that between the pressure sensor ( 5 ) and the pump ( 7 ) a separator ( 13 ) for volatile anesthetic gas and water and at least one of the separators ( 13 ) downstream filter ( 14 ) for CO₂ and organic Substances is arranged. 3. Anesthetic gas conduction system according to claim 2, characterized in that between the pump ( 7 ) and the filter ( 14 ) a check valve ( 10 ) with a downstream buffer memory ( 12 ) is provided. 4. anesthetic gas conduction system according to claim 1 to 3, characterized in that between the anesthetic excess gas outlet ( 3 ) and the pressure sensor ( 5 ) a check valve ( 8 ) for additional air from the outside and a check valve ( 9 ) for the anesthetic gas discharge line ( 15 ) to the outside is provided. 5. anesthetic gas conduction system according to claim 4, characterized in that the output of the separator ( 13 ) for volatile anesthetic gas to the anesthetic gas discharge line ( 15 ) with check valve ( 9 ), and this is connected downstream. 6. Anesthetic gas conduction system according to claim 1 to 5 ', characterized in that the pump ( 7 ) is followed by a check valve ( 11 ). 7. anesthetic gas conduction system according to claim 1 to 6, characterized characterized in that it is connected to a downstream Anesthetic gas recovery system is connected.   8. Anesthetic gas conduction system according to claim 1 to 7, characterized characterized in that the anesthetic gas contains xenon.