DE2156365A1 - Device preferably for anesthetic purposes - Google Patents

Description

DR. ING. E. HOFFMANN · DIPL. ING. W. EITLE DR. RER. NAT. K. HOFFMANN

PATBNTANWiLTB D-8000 MÖNCHEN 81ARABEUASTRASSE 4 TELEPHONE (0811) 911087

Soren Jorgensen, Odense / Denmark

Device preferably for anesthetic purposes

The invention relates to a device preferably for anesthetic purposes with a pipe system into which a mask, possibly an absorber to absorb the carbon dioxide, one or more check valves and a pipe socket for Supply of the anesthetic gas are inserted from a Rota counter.

A known device of this type has a breathing valve of the popoff type attached to the rubber bag in the pipe system. This valve is used to gradually divert excess anesthetic gas from the pipe system into the room where the device is located. This is disadvantageous insofar as the generally used narcotics have a teratogenic (teratogenic) effect. In addition, long-term exposure to nitrogen sub- oxides can cause aplastic anemia,

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and there appears to be a higher mortality rate due to malignant tumors among American anesthetists to be present in the blood cell-forming organs. Has conducted an investigation among Danish anesthesia workers showed that the incidence of spontaneous abortion increased from $ 10 to about $ 20 when working in a Anesthesia department had taken place where anesthetics were used.

Anesthetic gases are also excreted in systems without a breathing valve. This can be concluded, for example, from the fact that Employees in rooms where Fluothane anesthesia is administered have a proven record of Pluothane can be detected in the exhaled air up to half an hour after leaving the room. the Side effects such as headache and tiredness etc. are after a single day's work in the operating room known to all anesthetists.

It would be conceivable to press the anesthetic gases used down to floor level so as not to have any effect at head height to feel the same. It has been shown, however, that this procedure is not always sufficient. The anesthetic gases spread rapidly upwards and then exert the aforementioned influence on the persons concerned.

Taking these circumstances into account, the object of the present invention is to provide a system of the type mentioned to create a complete elimination of the anesthetic gas leaving the pipe system enables.

According to the invention, this object is achieved by

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that in the pipe system preferably near the rubber bag a branch pipe is installed, which is equipped with organs for a controlled suction of the anesthetic gas from the pipe system is coupled. This enables complete control of those leaving the pipe system of the device Anesthetic gases achieved and prevented the operator or himself in the vicinity of the device people are exposed to the harmful effects of the gases.

According to the invention, the organs for the controlled suction of the anesthetic gas can have a regulating valve provided electricity meter, its Output with a vacuum generating unit, e.g. a vacuum pump or a central vacuum system connected is. This will allow easy adjustment of the amount of electricity to be removed from the circuit, because the flow meter can easily be read while the valve is being adjusted. The setting of the valve must be adapted to the amount of current of the anesthetic gas that is fed to the rotary counter, so that a balance is achieved between the amount of electricity supplied and the amount drawn off. The flow meter is also easy to monitor.

Because the electricity meter only comes into contact with the exhaled If there is air from the patient, the system does not present a disinfection problem.

Furthermore, in the invention, a moisture absorber can be arranged in front of the electricity meter, and the electricity meter itself can be a Rota meter or a ball flow meter. This achieves a high level of operational reliability, since the Float or the ball of the flow counter of moisture be kept free.

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Furthermore, the moisture absorber can contain silica gel in a manner known per se, wherein the amount of this Ge3s should be at least 20g. This ensures that a flow meter from Rota counter type can work properly for at least 3 hours under normal suction conditions.

In addition, the flow meter can be converted into a rotary meter be installed while the moisture absorber is mounted on the side of the same. In this way it is easy to read off the amount of electricity sucked in and sucked in, on the other hand it is silica gel easily exchangeable. The replacement can easily take place during operation of the device.

The device according to the invention can also be used in connection with a respirator by the suction organs are mounted on the exhalation side of the respirator, with between the respirator and the A reservoir bag can be connected to suction organs. This achieves a very reliable operation of the respirator and careful removal of the exhaled air.

In addition, the moisture absorber can be attached easily replaceable by using a quick-release coupling is provided. This ensures that the moisture absorber can be removed and removed very easily can be replaced by a new absorber as soon as the absorption capacity of the gel is used up. Generally this is indicated by the indicator added to the gel changing color.

Furthermore, according to the invention, the vacuum-producing unit can be designed as an electric suction unit and with it

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Coupling the flow meter at the outlet of the same, while the inlet of the ejector suction unit to a Pipeline can be connected that leads to a window or ventilation duct in the work space. This ensures that the suction due to the constantly flowing propellant gas is very even from equip. There is hardly any heat development and the unit works completely independently from the electrical power supply. Incidentally, it should be noted that the anesthetic gas that the flow meter leaves, does not come into contact with the work area. The staff who operate the system are therefore against the anesthetic gas well protected.

According to the invention, the ejector suction unit can consist of an essentially T-shaped piece of pipe, the vertical part of which is closely connected to the outlet end of the flow meter, and its horizontal part contains two essentially frustoconical nozzle bodies, the narrowest ends of these bodies facing each other and being at a distance from each other, which is essentially equal to the inside diameter of the vertical pipe part, with the narrowest end of the nozzle body, which acts as a jet pipe, protrudes a little over the clear width of the vertical pipe part, and that the horizontal pipe part is provided with a nozzle for supplying and removing the propellant gas. This creates a Ejector suction unit created that is both simple is also operationally safe.

According to the invention, a shut-off valve, e.g. a ball valve be inserted in front of the jet pipe formed by the nozzle body, in the feed direction

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seen of the propellant gas is attached. This will achieved that the suction unit can be easily started and stopped without affecting the propellant gas supplying source needs to be regulated.

Finally, according to the invention, the ejector suction unit be set up so that it works with a propellant gas at a pressure of up to 6 atmospheres, as Propellant e.g. compressed air, nitrogen or oxygen can be used. This is the vacuum that the Suction unit delivers, sufficiently high. Embodiments of the invention are described in more detail below with reference to the drawing. Show it:.

Fig. 1 schematically shows an embodiment of an inventive Device for anesthetic purposes,

2 shows a flow meter provided with a regulating valve with an associated moisture absorber,

3 shows the device according to the invention in connection with a respirator,

4 shows a further embodiment of an inventive Device for anesthetic purposes with elimination of the anesthetic gases through an ejector suction unit,

Fig. 5 is a perspective view provided with a regulating valve Flow meter with associated moisture absorber and ejector suction unit, and

6 shows a longitudinal section through part of the ejector suction unit according to FIG. 5 on an enlarged scale.

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The one in Pig. 1 consists of a pipe system 1, in which there is an anesthetic mask 2, a check valve 3 *, a pipe socket 4 for the supply of fresh anesthetic gas, a carbon dioxide absorber 5 *, a branch pipe 6, a rubber bag 7 and another check valve 8. In operation of the device, the anesthetic gas will flow in the direction of the arrows in that the valve operator periodically compresses the rubber bag 67.

In the branch pipe 6 organs for a controlled suction of the anesthetic gas released by the system are mounted. These organs consist of a flow meter provided with a regulating valve and a vacuum generating unit 11, e.g. a central vacuum system or a vacuum pump.

Fig. 2 shows in detail how the flow meter, which is of the rotary counter type. Below he points a regulating valve 9, which can be shaped as a needle valve. This valve is in a manner known per se attached to an inlet pipe, which continues as a measuring tube, which extends around the longitudinal axis of the Flow counter extends. The inside of that tube communicates with an outer space around the measuring tube, and this outer space communicates with an outlet pipe 6a lower level of valve 9 · The pipe 6a is with the Vacuum unit 11 connected. The flow meter is on Inlet end connected to a moisture absorber 12 in the form of a water absorber which is at least 20 g Contains silica gel 13 as an absorbent. The absorber is made of plexiglass and has an open lid and a perforated base. By means of the rod 14 can the water absorber will be emptied. The anesthetic gas, which originates from the pipe system 1 according to FIG. 1, the

branch pipe 6 and reaches the upper end of the water absorber 12, after which it flows down through the silica gel. This flows at the lower end of the water absorber Gas into the flow meter and then up through the Needle tube and backwards along its outside. The float of the flow counter becomes an equilibrium position take by being influenced partly by gas and partly by gravity. From the flow meter the gas flows further into the vacuum unit. It it should be noted that the vacuum unit provides a constant negative pressure of e.g. 50 mm Hg. If desired, one branch off certain amount of electricity of the anesthetic gas from the pipe system 1, the regulating valve 9 is set until the flow meter shows the desired value. This value should be proportionate to the amount of electricity of the fresh anesthetic gas, which is fed from the rotary counter 16 to the pipe socket 4 in the system 1. As in Fig. As shown, the flow meter can be arranged together with the rotary meter 16. The water absorber 12 is placed outside the counter 16 so that the replacement of the silica gel can be carried out easily. Such a substitution is required if a color indicator added to the silica gel shows that the absorption capacity decreases against water. The gel can be changed while the system is in operation. possibly can the moisture absorber is fitted with a quick-release coupling so that it can be easily removed and replaced with a new one Absorber can be replaced.

If the flow meter is set correctly, the rubber bag 7 is not completely filled as in the usual System with breathing valve. This means that the only resistance the patient breathes against is the one to breathe through (tie check valves is given.

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The pipe system 1 is arranged in a circuit. Nothing stands in the way, however, that the system consists of one Pipe piece can exist, including the anesthetic mask and possibly an absorber, a rubber bag and possibly one or more check valves together with the suction devices are connected.

Nothing stands in the way of using the system described above in conjunction with an I70 respirator finds what is evident from FIG. A branch pipe I80 is partly on the breathing side of the respirator partly on the suction organs in the form of a flow meter I90 and one Vacuum system 200 connected. The system 200 can be located in a room outside the room in which the respirator is located and the flow meter is located, be provided, which is indicated by the dotted line 205. Inserted between the respirator and the flow meter a reservoir bag 210 is shown which is used for temporarily storing the exhaled air of the patient is used to determine which air is released into the pipe I80 in bursts.

Instead of the flow counter, you can use certain Cases are satisfied with a throttle valve.

The embodiment of the anesthesia apparatus according to the invention shown in Fig. 4 is shown in Fig. 1 of a pipe system 1 wherein an anesthetic mask 2, a check valve 3 1 a pipe connection 4 for the supply of fresh anesthetic gas, a carbon dioxide absorber 5 *, a branch pipe 6, a Rubber bag 7 and a second check valve 8 are included. When the system is in operation, the anesthetic gas will flow in the direction of the arrows when the valve operator periodically compresses the rubber bag 7.

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In the branch pipe 6 suction organs in the form of a flow meter 10 and an ejector suction unit 17 are attached, the latter at the outlet of the flow meter. The ejector suction unit is powered by a suitable propellant Propellant gas source 18 provided, which is under pressure. This source can e.g. consist of a pressure vessel, as shown in FIG. 5, however, it can also consist of a compressed air system. The propellant that is in the unit 17 is used, is routed away via pipeline 20, which extends up to a window or ventilation duct 21 in the work room continues.

As shown in FIG. 5, the ejector suction unit 17 is assembled with the flow meter 10. As shown, the flow meter is held between an upper and a lower rod 22 and 2j5 in a rectangular frame, and as shown in Fig. 2, it consists of a jacket tube 10a and a measuring tube 10b mounted therein. The upper end of the measuring tube 10b ¹ - ie the outlet of the same - is connected to a vertical pipe part 17a via a T-shaped pipe section with the ejector suction unit. The horizontal part of this pipe section bears the designation 17b, as shown in FIG. 6, and contains two essentially frustoconical nozzle bodies 20 and 21, the narrowest ends 20 ¹ and 21 'of which are directed towards one another. The distance a between these ends is essentially equal to the inner diameter of the pipe part 17a. The end 20 'protrudes a little beyond the clear width of the tubular part 17a. As shown in FIG. 5, a shut-off valve 23, which can be a cone valve, for example, is inserted into the pipe part 17b. At each end of the pipe part 17b, nozzles 24 and 25 are attached for the inlet and outlet of the propellant gas.

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In front of the flow meter, according to FIG. 5, ^θ ^ ^η moisture absorber 12 is used, which may contain silica gel, for example. This absorber is connected by means of a pipe 26 to the space between the jacket pipe 10a and the measuring pipe 10b of the flow meter. The connector 27 of the absorber is connected to the branch pipe 6 shown in FIG. 4.

At the lower end of the measuring tube 10b '(Fig. 5), a regulating valve 9 is inserted, whereby the flow the anesthetic gas can be easily regulated or stopped through the measuring tube. The flow meter 10, which is from Rota meter type, contains a float, which indicates the amount of current passing in a manner known per se.

The device according to FIGS. 4 to 6 operates in the following way Way: When the system is in operation, anesthetic gas is fed into the pipe system 1 via pipe socket 4, which is connected to the Rota counter is fed. At the same time, gas is sucked off through the branch pipe 6. This suction works in such a way Prepare that the fluctuations in the pressure of the anesthetic gas of the system 1 become very small, e.g. below 1/2 cm water column. The suction is brought about by means of the ejector suction unit 17 by forcing propellant gas through the same will - cf. the arrows A of FIG. 5. The propellant gas, which can possibly have a pressure of up to 6 atmospheres, is from The nozzle body 20 is shaped into a thin gas jet which hits the opening at the narrow end 21 'of the nozzle body 21, and as this jet travels further forward, it expands creating a negative pressure. This negative pressure causes the anesthetic gas to be displayed on measuring tube 10b of the flow meter. Before the anesthetic gas reaches this point is, it has, as shown by the small arrows, the silica gel in the absorber 12 passed so that it is largely

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is dry. As a result, the flow meter works very precisely. The volume flow that is extracted can be either can be regulated by means of the valve 9 or by reducing the propellant gas pressure on the pipe socket 24.

Various gases, e.g. compressed air, nitrogen or oxygen, can be used as propellants.

If the suction is carried out in the manner described above, there is no risk of the explosion suctioned anesthetic gases, as the gases do not get particularly hot and there is no possibility of them sparks get abandoned. The suction is also very evenly done, since the propellant gas is constantly the pipe section 17b happened.

The invention can be modified in many ways without departing from the spirit thereof will. Thus, the nozzle bodies 20 and 21 can have a larger or smaller apex angle than that shown. In addition, the distance between the bodies can be made smaller than shown.

The system described above serves only to illustrate the invention, not to limit the scope of protection.

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Claims (11)

Claims Device preferably for anesthetic purposes with a pipe system into one. Mask, possibly an absorber to absorb the carbon dioxide from the exhaled air, a rubber bag, possibly one or more Check valves and a pipe socket for supplying the anesthetic gas from a rotary counter are pushed in, thereby characterized in that in the pipe system (1), preferably near the rubber bag (7), a branch pipe (6, 6a) is mounted, with organs (10, Ix) for a controlled suction of the anesthetic gas from the Pipe system (1) is coupled. 2. Apparatus according to claim 1, characterized in that the organs for controlled suction of the anesthetic gas contains a regulating valve (11) provided with a flow meter (10), the outlet the former with a vacuum generating unit (H) * z. B. connected to a vacuum pump or a central vacuum system is. 3 · Device according to claim 1 or 2, characterized in that in front of the flow meter (10) a moisture absorber (12) is inserted, and that the flow meter, e.g. a Rota meter or a Ball flow meter is. 4. Apparatus according to claim 3, characterized in that the moisture absorber (12) in in a manner known per se contains silica gel (13), and that the amount of this gel is at least 20 g. 209821/0710 5. Device according to claims 1 to 4, characterized in that the flow meter (10) is built into the rotary meter (16), while the moisture absorber (12) is mounted to the side of the same. 6. Device according to claims 1 to 5 * thereby characterized in that it is adapted for use with a respirator (170) by the Suction organs (190 * 200) on the exhalation side of the Respirators are mounted, and that between the respirator (170) and the suction organs (190) a reservoir bag (210) is connected. 7. Device according to claims 1 to 5, characterized in that the moisture absorber is replaceably mounted and a quick coupling having. 8. Device according to claims 1 to 7, characterized in that the vacuum generating Unit designed as an ejector suction unit (17) and connected to the flow meter (10) at the outlet (105) of the same is, and that the outlet (25) of the ejector suction unit is connected to a pipe (20) which leads to a window or ventilation duct (21) in the work area leads. 9. Apparatus according to claim 8, characterized in that the ejector suction unit consists of a substantially T-shaped pipe section, the vertical part (ITa) of which is directly connected to the outlet (10b ¹ ) of the flow meter, and its horizontal part (17b) two contains essentially frustoconical nozzle bodies (20 and 21), the narrowest ends (20 ^f - 15 - 209821/0710 2156361 - -15 - and 21 ') facing each other and held at a distance (a) which is essentially equal to the clear width of the vertical pipe part ( ¹ Ta), the narrowest end (20 ^! ) of the DUsenkö'rpers (20), the acts as a jet pipe, protrudes a little over the clear width of the vertical pipe part (17a), and that the horizontal pipe part (17b) is provided with nozzles (24 and 25) for the supply and discharge of a propellant gas. 10. Apparatus according to claim 8 or 9 * thereby characterized in that in the horizontal part (17b) of the T-shaped pipe section a shut-off valve (23), e.g. a ball valve, is inserted in front of the nozzle body (20) formed by the jet pipe , seen in the direction of supply of the propellant gas, arranged is. 11. Device according to claims 8 to 10, characterized in that the ejector unit (17) can be acted upon with a propellant gas up to a pressure of 6 atmospheres, such as compressed gas as propellant gas Air, nitrogen or oxygen can be used. 2098P1 / 0710