SE449052B - Anaesthetic and/or respirator appts. - Google Patents

Abstract

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Description

For example, the treatment gas can be used to drive treatment liquid for, for example, anesthesia from a source of such liquid to a carburetor for mixing in the treatment gas. Preferably, said source is arranged to be under overpressure under the influence of the treatment gas and in connection with a gasification chamber via a mechanically and / or manually openable dosing valve. This eliminates the need for special dosing pumps for this treatment liquid. Instead, said valve may be arranged to be opened for a number of short periods, the dosage being dependent on the opening frequency resp. period length.

Preferably, the treatment gas is also used for tightness testing of the fan part by supplying a smaller part of it to this part during simultaneous pressure measurement.

Conveniently, the treatment gas is also used to control the supply of a second treatment gas, so that it cannot be supplied unless the former is supplied.

Preferably this is achieved by the plant being provided with two or more parallel connected lines connected to a corresponding number of gas sources for conducting the gas from these sources to the fan part, whereby pressure regulators are arranged in resp. lines in such a way that the supply of said second gas is regulated in proportion to the supply of the first gas and preferably so that it becomes equal to 0 under a certain minimum pressure for the first gas. For example, the supply of nitrous oxide N20 can be made dependent on the supply of oxygen.

The plant is suitably designed so that the treatment gas can also be supplied directly to the patient. This measure can be of great importance if something goes wrong at the facility or if the patient requires special treatment, e.g. supply of high-frequency pulsating air or oxygen via a needle directly into the airways.

A particularly economical and easily controlled system is provided, if the treatment gas is arranged to be recirculated in the patient part during measurement of both the gas supplied to the patient and the gas taken from the patient and possible comparison between these gases. In order to 10 15 20 25 30 35 D ÅA _ fi lï fi * f-f LJJL. To be able to quickly change the composition of the gas mixture in the recirculating system, the plant is suitably provided with a shunt line for directing at least one of the gases past the mixing point of the gases and past any carburettor directly to the fan part. In this way, the fan part can be quickly flushed clean of anesthetic gas.

For control and possible control of the mixing ratio between constituent gases, a flow meter is suitably arranged in each line upstream of a mixing point and preferably an additional flow meter downstream of this mixing point.

Through this arrangement, electrical signals representative of resp. flows. These signals can be used for control and regulation of these flows resp. for triggering alarms, if they exceed or fall below certain predetermined values. At the same time, these signals are a valuable aid in controlling the carburettor both in terms of the flow through this resp. supply of anesthetic fluid to it.

A further possibility to quickly change the composition of the gas mixture supplied to the patient can be provided with a direct line from a point after the mixing point of the gases and after mixing in any anesthetic gas past the main part of the ventilator part substantially directly to the patient. The treatment gas can also be used to drive the supply of prepared treatment gas from the ventilator part to the patient in the untreated state. This can be done, for example, by giving it in a manner known per se an opportunity to compress a bellows, a bladder or the like containing the prepared gas from the outside. An advantage that is gained in this case is that the same construction can also be affected directly or indirectly manually, when required. With regard to this function, more detailed reference is made to the co-pending Swedish patent application 84.03450-3 with the title "Anesthesia and / or respirator system with alternative manual drive".

Finally, the treatment gas of the present invention can also be used for more or less trivial functions e.g. to inflate a conventional blood pressure monitor or to operate a patient suction. This further simplifies the system as a whole while maintaining its versatility.

BRIEF DESCRIPTION OF THE DRAWING In the accompanying drawing, a substantially complete anesthesia system is schematically described in the form of a block diagram.

For practical reasons, the drawing has been divided into figure parts IA and IB with certain details shown on both figure parts.

PREFERRED EMBODIMENT OF THE INVENTION OF THE INVENTION The accompanying drawing thus shows a preferred embodiment of the present invention. 1, 2 and 3 are referred to here as three parallel inlet lines, which via check valves 4, 5 and 6 are connected to connections 7, 8 and 9 to gas sources (not shown), which can constitute fixed installations in a hospital. For filtering out any particles, lines 1, 2 and 3 contain filters 10, 11 and 12.

Alternatively, lines 1, 2 and 3 can instead be connected via lines 1a, Za and 3a to separate gas sources, e.g. solve gas tubes 7a, 8a and 9a. This is done in this case via non-return valves As, Sa and 6a and the filter and pressure control devices schematically shown in the drawing, which are denoted in their entirety by 13a, 14a and 15a.

In the system shown, it is intended that oxygen be supplied from sources 7 or 7a and nitrous oxide N20 from sources 8 or 8a. From source 9 compressed air is supplied and as an alternative from source 9a carbon dioxide CO2.

A first pressure control of the supplied gases takes place in the pressure control valves 16, 17 and 18, which are accompanied by fine control valves, e.g. needle valves 19, 20 and 21.

Thereafter, they obtain the flows through flow meters 22, 23 and 24 and an additional flow meter 25 arranged after the mixing point 26 of the gases. With the cross connection between the valves 16 and 17 it is indicated that the valve 16 is arranged to control the valve 17, so that the gas flow in the line 2 becomes dependent , e.g. proportional to that in line 1. 10 15 20 25 30 35 40 449 852 Via a valve 27 the gas mixture is then introduced into a single carburettor 28. Liquid is fed to this carburettor via lines 29, 30 and 31 with valves 32, 33 and 34 from either of three liquid sources 35, 36 and 37, which may contain, for example, halothane, enflurane or isoflurane. These liquid sources can be constituted by normal glass bottles, which can be connected directly to the lines 29, 30 and 31 via the double valves 38, 39 and 40.

Denoted by 35a, 36a and 37a are schematically indicated level meters for checking the level in the respective liquid source.

As can be seen from lines 41, 42 and 43 with valves 44, 45 and 46 and line 47 with pressure control valves 48 and 49, the liquid sources 35, 36 and 37 can be pressurized by means of gas either from line 1, ie oxygen or line 3. , ie compressed air.

Which is chosen is determined by means of the valve 50.

By means of the valves 44, 45 and 46 and the line 51, the liquid sources 35, 36 and 37 can be evacuated when they do not have to be under pressure. The line 51 is suitably connected directly to the hospital's normal evacuation system, e.g. via the collection valve 70 described in more detail below.

The pressures in line 2 resp. in the line 47 after the valve 50 is suitably read with the schematically shown pressure gauge 52, which may also contain a pressure gauge 52a for reading the pressure in the line 1, as shown in broken lines.

The gasification suitably takes place in such a way that one of the valves 32, 33 and 34 is opened periodically with a certain frequency and a certain period length. In this way a certain amount of anesthetic liquid is supplied to the carburettor 28, where according to a preferred embodiment of the object of the invention it is gasified on a heating table. If the energy supply and possibly the temperature for this heating table are checked, you get an additional measure of the amount of liquid supplied, which can thus be controlled in two ways. Regarding this function, further reference is made to the co-pending Swedish patent application 84.03447-9 with the title "Anesthesia and / or respirator system with a venting and / or gasification chamber". From the carburettor 28, the prepared mixing gas is fed via a line S3 with a valve 54 to either a first point 55 or a second point 56 in a recirculation system connectable to the patient 57. To the point 56, the gas is discharged via a shunt line S8 ', when a rapid change in the composition of the gas supplied to the patient is desired. Normally, however, it is conveyed to the point 55 which through a conduit 58 communicates with a blower or bellows structure 59 in a closed housing 60. When the blower or bellows structure 59 is subjected to an overpressure, the gas is forced through a choke 61, a check valve 62 and optionally a carbon dioxide absorbent 63 via a breathing mask 64 or the like to the patient 57. The inhalation takes place via a branch line 65 and the exhalation via a branch line 66.

The exhalation takes place via a throttle 67 and an exhalation valve 68 which is connected via a line 69 and a safety valve 70 to the hospital evacuation system.

Because the safety valve 70 is provided with two auxiliary valves 71 and 72, the patient's exhalation pressure can be kept within carefully defined limits. For example, the valve 71 may be arranged to be opened if the pressure is less than -1 cm H 2 O and the valve 72 if the pressure instead exceeds + 10 cm H 2 O. Normally, however, only a small part of the exhaled gas is discharged via the valve 68. The main part is instead recirculated patients 57.

In this case, the circulating current is measured partly over the throttle valve 61 and partly over the throttle valve 67. This is done with the aid of schematically shown pressure gauges 75 and 76, which thus measure the pressure drop across resp. throttling and thus the flow through it. For further control, the flow meter 76 is coordinated with a pressure gauge 77.

Dashed lines indicate that the carbon dioxide absorber 63 may alternatively be replaced by an absorbent 63a in the exhalation line 66.

The driving force for the bladder or bellows structure 59 is taken from either of the lines 1 or 3 via the valve 50 and the lines 47 and 78. The latter line contains partly a valve 79 and partly a double valve 80. The valve 79 is controlled in such a way that pressure is applied to the housing 60 10 15 20 25 30 35 7 Åf4-9 052 during the periods when inhalation is desired. If, for some reason, this is to be achieved manually instead, this can be done by means of a second blowing or bellows construction 81, which via the double valve 80 is also connected to the closed housing 60. The valve 80 is arranged so that the line 78 is automatically disconnected , when the blower or bellows structure 81 was subjected to a manual pressure. The blower or bellows structure 81 is inflated by means of propellant gas from line 78 via a line 82 with a choke 83 and a distribution valve 84. By means of the latter valve the structure can also be vented via an evacuation line 85.

Between the valves 79 and 80 there is a schematically shown control valve 86 connected to an evacuation line 87. By means of this valve the so-called PEEP pressure, ie a certain minimum pressure at the end of a patient's exhalation. This valve is also opened if the pressure in the pressure gauge 77 should show an excessively high value. Alternatively, the pressure gauge 77 opens the valve 88, through which the closed housing 60 communicates with an evacuation line 89.

Via lines 90 and 91, samples can be taken partly from the patient's exhalation gas and partly from line 53 directly after the carburettor 28. Line 90 is via a filter 92 and line 91 directly connected to a changeover valve 93.

The samples are then passed via an additional changeover valve 94 to an anesthetic gas meter 95 and an oxygen meter 96.

Regarding the construction of the anesthetic gas meter, reference is made in more detail to U.S. Patent 4,399,686. Furthermore, regarding the construction and function of the pipes, reference is made to Swedish Offenlegungsschrift 428 345.

Via the changeover valve 94, calibration gas can be supplied from a connecting line 97. The samples are then sucked via a throttle 98 by means of a pump 99 back into the line 53.

As a safety measure, treatment gas is taken via the line 100 with the non-return valve 101 from the line 1 to a tank 102. Should the pressure drop in the line 1, this compressed air is blown out in a manner known per se through a whistle 103. 10 15 20 25 30 35 449 052 ß Treatment gas is also taken from line 1 via line 104, a line 105 and a schematically shown pulse generator 106 to a patient connection 107. This connection can for instance consist of a needle directly insertable into the patient's airways, which is supplied with a pulsating pressure with a frequency substantially above what is common for normal breathing, e.g. 10 times above normal.

This system is used, for example, if the airways cannot be reached in any other way.

Treatment gas can also be conveyed from line 1 via line 104, a filter 108, a valve 109 and a pressure regulating device 110 via a line 111 to a point after the carburetor 28. If gas is supplied this way under a greatly reduced pressure during simultaneous pressure measurement, the fan part density can be checked . If the pressure does not rise, the leakage is equal to or greater than the amount of gas supplied.

Via an additional shunt line 112 with a valve 113 and a throttle 114, treatment gas from the line 1 can be passed past the carburettor 28. This line system was used to quickly flush the fan part free of drug gas.

The line with its throttle and valve are therefore relatively roughly dimensioned, so that such a rapid flushing can be achieved.

With the designations 115 resp. 116 and a number of diagrammatically shown valves and throttles without designations indicate how the treatment gas from the line 47 can be used partly for driving a patient suction 115, partly for inflating a cuff belonging to a conventional blood pressure monitor 116.

With line 117 it is indicated how the patient's face mask can be arranged to be evacuated directly. Regarding this function, reference is made in more detail to Swedish patent 428,757.

Finally, regarding the function of the fan part, reference is made to, for example, U.S. Patent 4,421,113.

However, it can of course also be operated in many other ways known per se. The invention is of course not limited to the embodiment described above only, but can be varied within the scope of the appended claims, all of which have in common that the treatment gas is to be used as efficiently as possible for several functions.

Finally, it can be mentioned that the present invention is preferably intended to be used together with the inventions described in the co-pending patent applications 84.03450-3 (ENG 048) "Anesthesia and / or respirator system with alternative manual drive", and 84.03447-9 (ENG 049 ) "Anesthesia and / or respirator system with a humidification and / or gasification chamber". The contents of these patent applications are therefore incorporated into the present application.

Claims (8)

10 15 20 25 30 449 052 10 PATENT REQUIREMENTS Anesthesia plant comprising one or more sources (7, 8, 9; 7a, Sa, 9a) for treatment gas and one or more sources (35, 36, 37) for anesthetic liquid and a carburettor for gasifying the anesthetic liquid and mixing it in the treatment gas , before it is supplied to the patient (57) by means of a fan part (55-56, S8-68), the treatment gas also being used to fulfill one or more additional functions in the system, characterized by one or more bypass lines for directing the treatment gas to the patient (57) while bypassing one or more functions in the plant. Plant according to one of the preceding claims, characterized in that the treatment gas is arranged to be able to be supplied directly to the patient (S7, via lines 104, 105, 106 and 107) without admixture of gasified anesthetic liquid. ' Plant according to claim 2, comprising two or more parallel-connected lines (1, 2, 3) connected to a corresponding number of gas sources (7, 8, 9; 7a, 8a, 9a) for conducting the gas from these sources to the fan part (55 -56, 58-68), characterized by in resp. lines (1, 2, 3) arranged pressure regulators (16, 17, 18), of which two (16, 17) are arranged so that the pressure after one (17 in line 2) of them is regulated down proportionally and preferably becomes zero below a certain minimum pressure in the second line (1). Plant according to claims 2 and 3, characterized by a downstream pressure regulator (16) in one (1) of the gas lines (1, 2, 3) outgoing side line (104, 105), which via a further preferably as pulse - generator operating control valve (106) and possibly a shut-off valve (107) is arranged to be able to be connected directly to the patient (57). u! n. 10 15 20 1 * 449 o ° \ Jd_ Plant according to claim 2, characterized in that at least one of the gases is arranged to be able to be led via a shunt line (112) past the mixing point (26) of the gases and past any carburettor (28) directly to the fan part (55-Sun). , 58-68) e.g. for flushing this. Plant according to claim 2, characterized by a direct line (58 ') from a point after the mixing point (26) of the gases and after mixing anesthetic gas in the carburettor (281 past the main part of the fan part (55-56). , 58-68) substantially directly to the patient (57). Plant according to one of the preceding claims, characterized in that the treatment gas is also used for tightness testing of the fan part (55-56, 58-68) in that a smaller part of the same is supplied to this part (via 104, 108, 109). 110, lll) during simultaneous pressure measurement. Plant according to any one of the preceding claims, characterized in that the treatment gas (in line 1) is used to control the supply of a second treatment gas (in line 2), so that this can not be supplied, unless the first-mentioned added.