DE3708146A1 - Respiratory gas apparatus - Google Patents

Abstract

An apparatus (1) (Fig. 1) is intended to supply a patient with respiratory gas and essentially comprises a source (2) of respiratory gas and a nasal tube (3). Within the respiratory gas supply, between the source of respiratory gas and the nasal tube (3), there is a valve (12) which is in control connection with a measurement device (10) having a sensor (9). In the region near the nose the sensor (9) is inserted in a small nose pipe (6) of the nasal tube (3) and measures the temperature difference at the change between inspiratory and expiratory phase. The measurement device (10) is used to close the valve (12) during the expiratory phase and thus to interrupt the supply of respiratory gas. A respiratory gas intermediate store (22) inserted within the respiratory gas supply in front of the valve (12) is capable of receiving the respiratory gas produced in the expiratory phase, and this stored respiratory gas is then available in the inspiratory phase together with that continuously produced by the source of respiratory gas. <IMAGE>

Description

The invention relates to a device for feeding Breathing gas to a patient, with a breathing gas source as well an attached nasogastric tube that has at least one nasal tube engaging in a nostril with a Breathing gas connection and a breathing gas outlet opening, and with a measuring device having a sensor for Detect the change between the inspiration phase and exspi ration phase and one in the breathing gas supply Lichen valve, which can be closed in the expiration phase is controlled by the measuring device.

Such devices can be used as oxygen sources Oxygen concentrators, oxygen tanks or central Breathing gas supply systems serve. The disadvantage of these is Systems that also exhale the breathing gas during the exhalation phase drove remains, so that a considerable part of the Breathing gas production escapes unused into the ambient air and thus there are high losses. So you have a front Direction of the type mentioned in the introduction via probes in the gas supply system detects the alternation of inhalation and exhalation and the breathing gas via a valve during the exhalation phase drove interrupted. This has turned out to be disadvantageous asked that the system works comparatively sluggish because the change between inhalation and exhalation is not exact or can only be detected with a delay, so that in the off breathing phase does not switch off over the full period the breathing gas supply can take place. This results in a  only minimal breathing gas savings.

The object of the present invention is to provide a direction of the type mentioned at the beginning of the breathing gas losses to reduce significantly overall. In particular, by the invention also has the option of being used an oxygen concentrator with comparatively ge small size of this and consequently also with ge ringer heat and noise, what before desirable especially in long-term oxygen therapy is. Finally, the measuring device, the Sensor and its arrangement take up little space and effort require.

To solve this problem, the invention in particular whose proposed that the ver with the measuring device bound sensor on the nasal tube in the way of the Exhaled dispensed, used breathing gas arranged is.

This is done with this patient-controlled device Detect the alternation between inhalation and exhalation practically immediately at the "place of action", namely close to the nose, which means essentially no delay this change is detectable and accordingly the shutdown valve can also be controlled directly when changing. Otherwise during the exhalation phase to the ambient air The lost breathing gas released can be almost complete dig be saved. This also results in the essential advantage that one can use in particular of oxygen concentrators with less Size gets along.  

A preferred embodiment provides that the nasal Tubes in addition to the breathing gas connection and the breath gas outlet opening a second outlet opening for the Exhausted, at the breathing gas outlet opening breathing air entering during exhalation and that the sensor inside the tube between the two outlet openings is arranged.

In this embodiment, the is in the tube alternately with a newly added sensor Breathing gas and then with exhaled air directly applied, which is very clear and set sharply defined measurement signals, which are under other are also easy to evaluate.

The tube expediently has at its ends on the one hand the breathing gas outlet opening and on the other hand the second outlet opening and at a distance from it End openings a side wall opening as breathing gas connection on. Such a tube results on the one hand favorable flow conditions on the one hand for feeding of the breathing gas and on the other hand also when flowing through and exposing the sensor to exhaled air. In addition, such a tube can be easily manufactured len.

The sensor is advantageously inside the tube between the breathing gas outlet opening and the breathing gas finally ordered. The sensor is therefore directly in each because of supplied breathing gas and removed, consumption breathed area.

The tube expediently has an outer sleeve in this way like one used in it, over a sub-area of the outer sleeve extending inner sleeve, the Inner sleeve preferably circular in cross section sectional wall recess for receiving a  Control line for the sensor has. The control line and possibly also the sensor located at its end can be pre-selected within the tube fix the place, including the assembly of this Tube is easy to carry out.

A pressure sensor or a flow sensor, preferably a temperature sensor can be provided. Ins special the temperature sensor is also under the gentleman reliable operating conditions and thus takes little space that it fits well within the nasal tube can be used.

It is useful if the sensor is next to the side the through hole of the inner sleeve at whose breath end facing the gas outlet opening within the Outer sleeve is arranged and preferably one in the Has gas flow protruding contact tab. The sensor itself is next to the passage channel for the breathing gas arranged, while the contact lug in the Gas channel protrudes and thus for a good transmission of the the size measured, in particular the temperature, serves.

In a device of the type mentioned, wherein an oxygen concentrator serves as the breathing gas source according to a development of the invention provided that between the oxygen concentrator and that in the breath gas supply valve located a breathing gas intermediate memory is provided. This results on the one hand the possibility of regarding the oxygen concentrator to reduce its power output, so that one in in this case with a smaller size and among others comes up with lower power consumption, which for the mobile use of such devices is advantageous. These Output reduction is possible because the breathing gas release from the nasogastric tube during the exhalation phase  the valve is blocked, so that in this phase the respiratory gas produced in the oxygen concentrator Interim storage promoted and then in the one breathing phase together with the ongoing production of the concentrator is then available. This also gives you the option of using larger size given an oxygen concentrator Amounts of oxygen or respiratory gas during inhalation phase.

Additional embodiments of the invention are in the further subclaims listed. Below is the Invention with its essential details based on Embodiments explained in more detail.

It shows:

Fig. 1 is a partly in section of nasogastric tube with a schematically indicated power system,

Fig. 2 is a longitudinal section of a belonging to a nasogastric tube, nose,

Fig. 3 is a front view of the nasal tube 2 shown in Fig. 2 with the sensor and

Fig. 4 is a Fig. 3 corresponding view of a nasal tube without an inserted sensor.

An apparatus 1 shown in Fig. 1 is used for the supply of breathing gas to a patient, said here as the breathing gas source is an oxygen concentrator 2 is provided. The breathing gas is fed into a patient's nose 4 via a nasal probe 3 . In the exemplary embodiment, the nasal probe has two nasal tubes 5 , 6 engaging in the nostrils, which together with a breathing gas supply part 7 form the nasal probe 3 . The one nasal tube 5 forms together with the breathing gas supply part 7 an integrally connected, T-shaped part which has a transverse bore 8 at a distance from the nasal tube 5 , into which the second nasal tube 6 is inserted. The respiratory gas supply takes place at opposite ends of the respiratory gas supply part 7 , with corresponding hose pieces 11 being indicated in FIG. 1.

The device 1 also includes a measuring device 10 , which is in control connection with a sensor 9 , and a valve 12 in the breathing gas supply 11 , which can be controlled by the measuring device 10 .

With the help of the sensor 9 , the measuring device 10 and the valve 11 , the breathing gas supply can be interrupted during the breathing phase. This results in a significant saving of breathing gas compared to the previously common systems, where the breathing gas supply was continuously continuous both during the inhalation phase and during the exhalation phase.

In the exemplary embodiment, the sensor 9 is designed as a temperature sensor. He is housed in the embodiment half of the nasal tube 6 and angeord net that he can be acted upon alternately by both the supplied breathing gas and the exhaled air. Since the supplied breathing gas and the expelled, used breathing air show significant temperature differences, the change between inhalation and exhalation can be clearly measured.

In order to achieve this largely exclusive exposure to the sensor either with exhaled air or with supplied breathing gas, the nasal tube 6 has, in addition to a breathing gas connection 13 (see also FIG. 2) and a breathing gas outlet opening 14, a second outlet opening 15 , from which the used air can escape during exhalation, the nasal tube 6 being flowed through by this used air and thereby acting on the sensor 9 . During exhalation, the used air enters the breathing gas outlet opening 14 , flows through the tube 6 and then exits at the outlet opening 15 . During the subsequent inhalation, some outside air is sucked in through the tube 6 past the sensor via the outlet opening 15 , this outside air being cooler than the exhaled air, so that the sensor can practically pass on the temperature jump as a measured variable to the measuring device 10 , which in turn the valve 12 for the breathing gas supply opens. When changing between inhalation phase and exhalation phase, the temperature difference between the supplied breathing gas and the exhaled air is measured, while when changing between exhalation phase and inhalation phase, the temperature difference between exhaled air and ambient air is measured. The temperature differences are each so large that the valve 12 can be switched almost without delay. Is particularly advantageous, the arrangement of the sensor shown in Fig. 1 and 2, this is both within the communication passage between the respiratory gas outlet opening 14 and the outlet opening 15, on the other hand and also between the respiratory gas discharge port 14 and the respiratory gas connection 13. This particularly advantageous arrangement gives the possibility of reacting very quickly when changing between the inspiration phase and the expiration phase.

The nasal tube 6 has an outer sleeve 16 and a somewhat shorter inner sleeve 17 inserted therein, where one end of the inner sleeve ends at a distance from the breathing gas outlet opening 14 of the outer sleeve 16 . At this end, the temperature sensor 9 is arranged laterally next to the through hole of the inner sleeve. It has a contact flag 18 projecting into the gas flow, which is clearly visible in the front view in FIG. 3. The inner sleeve 17 has a wall recess 23 which extends over its length and is approximately circular in cross section for receiving a control line 19 connected to the sensor 9 . A temperature sensor is preferably used, but there is also the possibility of using a pressure sensor or a flow sensor. Depending on the sensor used, structural adjustments may be required compared to the examples shown in the figures.

In Fig. 1, the nasal tube 6 is seen via its outlet opening 15 with an extension tube 20 ver, which can be formed, for example, by an attachable piece of tubing ge. By varying the length of this piece of hose, the switchover point of the valve can be influenced during the change between inhalation and exhalation.

As already mentioned, the breathing gas supply part 7 has a transverse bore 8 for receiving the sensor nasal tube 6 . In order to achieve a secure connection between these two parts, the tube 6 is provided with a puncture 21 which is matched to the cross section of the breathable gas supply part being penetrated. Since the parts are made of plastic in particular, they give a little when inserting the tube 6 and then lock in the end position of the tube 6 . The breathing gas connection 13 is also located within the recess 21 . The cross section of the tube in this area is dimensioned such that the cross section of the breathing gas supply part 7 is practically filled out, so that the breathing gas supplied practically finally ends up in the breathing gas connection 13 .

The further nasal tube 5 is supplied via the connection on the breathing gas supply part 7 opposite.

In Fig. 1 it can still be clearly seen that the outer cross section of the tube 6 is larger than that of the tube 5 , so that exhaled air for the action of the sensor 9 also largely passes through the tube 6 . In the other tube 5 , the exhaled air passes laterally between the nostril wall and tube 5 into the ambient air. In the case of this tube 5 , a modified embodiment of the sensor arrangement is also shown in broken lines, this being arranged on the tube outside and outside of the nose insertion region. In this embodiment, the sensor 9 a is alternately exposed to warm, exhaled air and cooler ambient air when inhaled. Here, too, there are comparatively steep-sided temperature jumps in the sensor which can be evaluated well for reversing the valve 12 . The ge with the tube 6 showed embodiment with arrangement of the sensor within half of the tube is the preferred one, since here the sensor is well protected.

Stoffkonzentrator 2 as a source of breathing gas in particular in a device 1 with an acid can be provided between the oxygen concentrator 2 and the valve 12, a breathing gas latches 22 located in the breathing gas supply. In the exhalation phase, where the valve 12 interrupts the supply of breathing gas to the nasal probe 3 , breathing gas can be produced practically in reserve and is then available in the inhalation phase together with the ongoing production from the oxygen concentrator 2 . Thus, a larger amount of breathing gas can be made available during the inhalation phase than the oxygen concentrator 2 can produce even in this time period. The storage volume of the buffer store is expediently dimensioned such that it corresponds approximately to the production amount of breathing gas from the concentrator 2 during the closing time of the valve 12 . For example, the filling volume can be 2 to 10 liters, preferably about 5 liters. In addition to the possibility of a greater release of oxygen in the inhalation phase, the breathing gas buffer 22 can, if necessary, also use an oxygen concentrator 2 of a smaller size than previously customary.

All in the description, the claims and the drawing Features shown can be both individually and also in any combination with each other be essential.

Claims (16)

1. Device for supplying breathing gas to a patient, with a breathing gas source and a nasal probe connected to it, which has at least one nasal tube engaging in a nostril circuit with a Atemgasan circuit and a breathing gas outlet opening, and with a sensor having a measuring device for detecting the Alternating between the inspiration phase and expiration phase and a valve located in the breathing gas supply, which is controlled by the measuring device for closing in the expiration phase, characterized in that the sensor ( 9 ) connected to the measuring device ( 10 ) on the nasal tube ( 6 ) is arranged in the way of the exhaled breathing gas given on exhalation. 2. Device according to claim 1, characterized in that the nasal tube ( 6 ) in addition to the breathing gas connection ( 13 ) and the breathing gas outlet opening ( 14 ) a second outlet opening ( 15 ) for the exit of used, at the breathing gas outlet opening ( 14 ) has breathing air entering during exhalation and that the sensor ( 9 ) is arranged within the tube ( 6 ) between the two outlet openings ( 14 , 15 ). 3. Apparatus according to claim 1 or 2, characterized in that the tube ( 6 ) at its ends on the one hand the breathing gas outlet opening ( 14 ) and on the other hand the second outlet opening ( 15 ) and at a distance from these end openings a side wall opening as a breathing gas connection ( 13 ) having. 4. Device according to one of claims 1 to 3, characterized in that the sensor ( 9 ) within the tube ( 6 ) between the breathing gas outlet opening ( 14 ) and the breathing gas connection ( 13 ) is arranged. 5. Device according to one of claims 1 to 4, characterized in that the tube ( 6 ) has an outer sleeve ( 16 ) and an inserted therein, extending over a portion of the outer sleeve inner sleeve ( 17 ), and that the inner sleeve in a Cross-section, preferably circular-section-shaped wall recess ( 23 ) for receiving a control line ( 19 ) for the sensor. 6. Device according to one of claims 1 to 5, characterized in that a pressure sensor or a flow sensor, preferably a temperature sensor, is provided as the sensor ( 9 ). 7. Device according to one of claims 1 to 6, characterized in that the sensor ( 9 ) is arranged laterally next to the through bore of the inner sleeve ( 17 ) on the face of the respiratory gas outlet opening ( 14 ) facing inside the outer sleeve ( 16 ) and preferably one has contact tab ( 18 ) protruding into the gas flow. 8. Device according to one of claims 1 to 7, characterized in that the from the breathing gas connection ( 13 ) to the second outlet opening ( 15 ) extending tube section is variable in length, preferably by attachable, different lengths of hose pieces ( 20 ). 9. Device according to one of claims 1 to 8, characterized in that the nasal probe ( 3 ) has a preferred, T-shaped breathing gas supply part ( 7 ) with gas supplies located on opposite sides and a first nasal tube ( 5 ) and that a Another nasal tube ( 6 ) equipped with a sensor ( 9 ) is inserted into a transverse bore ( 8 ) of the breathing gas supply part ( 7 ). 10. The device according to claim 9, characterized in that the inserted into the breathing gas supply part ( 7 ) tube ( 6 ) has a groove-like, on the cross section of the penetrated breathing gas supply part ( 7 ) tuned groove ( 21 ), in the area of the breathing gas connection ( 13 ) of the sensor tube ( 6 ) and that the tube ( 6 ) essentially fills the inner cavity of the breathing gas supply part. 11. Device according to one of claims 1 to 10, characterized in that the ge to the nasogastric tube ( 3 ) hearing parts are essentially made of plastic be. 12. The device according to one of claims 1 to 11, characterized in that the cross section of the nasal tube ( 6 ) equipped with a sensor ( 9 ) is dimensioned such that the nostril cross section is largely filled. 13. The apparatus according to claim 1, characterized in that the sensor is arranged outside and outside of the nose insertion area on a nose tube ( 5 ). 14. The device in particular according to one of claims 1 to 13, wherein an oxygen concentrator is used as the respiratory gas source, characterized in that a respiratory gas intermediate store ( 22 ) is located between the oxygen concentrator ( 2 ) and the valve ( 12 ) located in the respiratory gas supply. is provided. 15. The apparatus according to claim 14, characterized in that the storage volume of the intermediate store ( 22 ) corresponds approximately to the production amount of breathing gas of the concentrator ( 2 ) in the closing time of the valve ( 12 ) during use. 16. The apparatus of claim 14 or 15, characterized in that the breathing gas buffer ( 22 ) has a filling volume of about 2 liters to 10 liters, preferably about 5 liters.