DE10203079A1 - Respiratory flow measurement device - Google Patents

Abstract

The invention relates to a device for measuring respiratory flow, said device comprising a magnetic field sensor (111) which is detachably applied to a respiratory air guiding device (102), for example a mouthpiece, on the outside. Furthermore, the respiratory air guiding device is provided with a device (113) for producing a magnetic field, said magnetic field surrounding the magnetic field sensor. An influencing device (114), for example in the form of a ferromagnetic strip, is arranged inside the respiratory air guiding device (102), said influencing device being moved by the respiratory air flow A which is guided through the respiratory air guiding device (102), and causing a change in the magnetic field. The change in the magnetic field generates a corresponding output signal of the magnetic field sensor, which can be used as a measuring signal. The detachable arrangement of the magnetic field sensor (111) on the respiratory air guiding device enables the inventive device for measuring respiratory air to be thoroughly cleaned and autoclaved once the magnetic field sensor has been removed.

Description

The present invention relates to a Respiratory flow measuring device.

The sensory / metrological recording of the human Breathing places special demands on those used Equipment. So, especially when used in therapeutic environment, high accuracy can be achieved so that the derived measured values are used in a targeted manner can be. Also in the diagnostic area reliable measured values can be obtained. At the same time the devices used are easy to clean and sterilize to be a repeated use at different To enable people.

The two requirements discussed previously, namely Measuring accuracy on the one hand and very good Cleanability including sterilizability lead to oppositely oriented technical Design features as there are regularly high-precision measuring systems are difficult to clean and cannot be sterilized.

On the other hand, it is easy to clean and robust Measuring systems hardly the desired therapeutic / diagnostic Achieve measurement accuracy.

There are several in the medical-technical field Respiratory flow measuring devices known. This is how EP 0 091 522 A describes a sensor in which a Patient arranged spiral wire together with the housing surrounding it forms a capacitor whose Change in capacity is evaluated as a measured variable. The Sensor only allows the determination of whether a Breath flow is present, but not the measurement of the size or the direction of the air flow.

WO 98/36245 A describes a very complex respiratory flow detector known in which a flap is used which the Breathing air line closes almost completely and through the patient's breathing air is deflected. On the flap are arranged magnets, whose magnetic field from outside the Hall sensors positioned for breathing air detection becomes. The displacement of the flap leads to a displacement of the magnets so that on the Hall sensors accordingly shifted magnetic field acts. This The magnetic field is shifted in by the Hall sensors implemented an electrical signal that for metrological Purposes can be used. Overall, the structure this known device expensive, especially since the flap which the permanent magnets are attached by a spring be brought into a rest position related to the two Hall sensors is precisely defined. Only if this Zero point setting is defined, is with the two Hall sensors of the known device reliable measurement result achieved. As a priority The device is used in WO 98/36245 A indicated the treatment of apnea patients. Other Uses are only mentioned in passing, without one special design or adaptation of the device explained becomes.

The last described and known from WO 98/36245 A. Device is suitable due to its complex structure not for inhalation therapy devices because it is regularly deals with devices that the patient for the Personal use can be made available so that due to the resulting number of pieces Inhalation therapy devices are particularly inexpensive have to be manufactured. It is also necessary that Patients for the independent implementation of a Inhalation therapy an inhalation therapy device on hand to give, in which all components, too Respiratory flow measuring devices easy to use and thorough are to be cleaned. It cannot be assumed that in the patient using the device special Experience in handling these devices or technical Understanding exists. In particular, from the patient elaborate adjustment processes or checks of defined zero positions are not required.

With this in mind, the present invention has Aim to be a respiratory flow measuring device, especially for the To provide use in inhalation therapy devices, the simple and uncomplicated structure of the patient in the situation, the respiratory flow measuring device and also that equipped with the respiratory flow measuring device Inhalation therapy device easy and safe to use. In addition, the invention pursues the goal of a Respiratory flow measuring device to specify the required Measurement accuracy for use in therapeutic / diagnostic area provides that the use in medical-technical devices, in particular Inhalation therapy devices is possible. So immediately connected is the further object of the invention, a Respiratory flow measurement device that is easy to clean and to sterilize, in particular autoclave.

The invention is based on the finding that it is suitable for Achieving the above goals is necessary and is sufficient, a magnetic field sensor and a Device generating a magnetic field outside of a Arrange breathing air guidance device and in the Breathing air guidance device and thus in the breathing air flow a device that changes the magnetic field provided. These three components need to be spatial are positioned in a coordinated manner, in such a way that on the one hand that from the magnetic field generating device generated magnetic field surrounds the magnetic field sensor and the change caused by the influencing device of the magnetic field also in the area of the magnetic field sensor to such an extent that a corresponding Output signal of the magnetic field sensor is caused. The Arrangement of the magnetic field sensor and a magnetic field generating facility outside of Breathing air guidance device leads to this Components not in direct contact with the air we breathe come. There is therefore no cleaning problem negligible. If the two components or at least the magnetic field sensor detachable on the Breathing air guidance device can be held, the Breathing air guidance device together with the the magnetic field changing influencing device after the replacement of the two other components or the magnetic field sensor be thoroughly cleaned and sterilized. Subsequently becomes the magnetic field sensor or the one generating a magnetic field Device again on the breathing air guidance device attached.

A simple structure is achieved in particular if the breathing air guidance device in the form of a short Pipe piece is realized in which the inside Influencing device is arranged and on the outside Magnetic field sensor and magnetic field generating device are attached. As mentioned earlier, is done with regard to the cleaning according to the invention at least the attachment of the Detachable magnetic field sensor.

A particularly simple design results when Influencing device a short ferromagnetic Strip is arranged in the breathing air guidance device, due to the choice of materials and the dimensions has sufficient inherent stiffness to be self-supporting spring element in the air flow to be able to be arranged. This ferromagnetic The easiest way to strip is in a base that preferably in one piece with the breathing air guidance device is formed, for example by being in a suitable slot is clamped in the base. The Strips can also be made in the material of the base incorporated, d. H. to be reshaped so the bracket continue to improve.

A further improvement in the measurement signal can be found easily achieved by the fact that the ferromagnetic Strip comprises two sections, one of which is first Section essentially perpendicular to the air flow in the breathing air guide device is arranged and of the a second section angled to the first section runs. The angled second section is there preferably arranged in the vicinity of the magnetic field sensor, when the resilient strip is in its rest position.

The above objects of the invention are achieved by the provision of a respiratory flow measuring device with a Breathing air guidance device through which the breathing air inside of a patient whose breath flow is to be measured is feasible with a magnetic field sensor that changes of the magnetic field surrounding it emits an output signal and which is releasably arranged on the outside of the breathing air guidance device is, with a magnetic field generating device, which in Regarding the magnetic field sensor on the Breathing air guidance device is arranged such that the magnetic field generated by the magnetic field generating device surrounds the magnetic field sensor, and with one the magnetic field changing influencing facility in relation to the Magnetic field sensor and magnetic field generating device is arranged that a spatial shift of the Influencing device a change of the Magnetic field sensor surrounding magnetic field causes and in Arranged inside the breathing air guide device and is held by one by the Breathing air guidance device guided breathing air flow at least is moved to such an extent that the caused changing influence of the magnetic field Output signal of the magnetic field sensor causes.

In an advantageous embodiment, the respiratory flow measuring device according to the invention characterized in that the influencing device compared to the Breathing air guidance device is fixed that the movement of the Influencing device takes place around a rest position.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the influencing device compared to the Breathing air guidance device is resiliently fixed so that it automatically returns to the rest position if none Breathing air flow acts on them.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the influencing device is designed in the form of a strip is.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the influencing device has a first section has, which is substantially transverse to the flow direction of the through the breathing air guidance device guided air flow is arranged, and comprises a second section, the angled to the first section.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the angled second section of the Influencing device in close proximity to the Magnetic field sensor is arranged.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that with resilient and related to a rest position the influencing device in the Breathing air guiding device the angled second section the influencing device in close proximity to the Magnetic field sensor is arranged when the Influencing device is in the rest position.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention in that the angled second section of the Influencing device the magnetic field sensor is arranged opposite when the Influencing device is in the rest position.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the breathing air guiding device is a piece of pipe Mouthpiece or a breathing air channel.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the magnetic field sensor is a Hall sensor.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the magnetic field sensor is arranged in a housing, that is arranged detachably on the breathing air guidance device.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the device generating the magnetic field Is permanent magnet.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the magnetic field generating device from the Breathing air guidance device is detachable.

In a further advantageous embodiment, stands out the respiratory flow measuring device according to the invention that the magnetic field generating device in a housing is arranged that releasably on the breathing air guide device is arranged.

With regard to an important field of application is with the help the invention an inhalation therapy device with a Inhalation nebulizer created by one Compressor compressed air for nebulizing one in the Inhalation therapy nebulizer can be supplied with stored substance is, and with a respiratory flow measuring device of the previous explained type that on the Inhalation nebulizer is arranged that the air we breathe of the user through the breathing air guidance device is passed through.

Furthermore, an inhalation therapy device with a Inhalation therapy nebulizer created in which a membrane Aerosol generator for nebulizing an atomizer Liquid is arranged with a control device for Control of the membrane aerosol generator and with a Respiratory flow measuring device of the type explained above, which is such is arranged on the inhalation therapy nebulizer that the Breathing air of the user through the breathing air guidance device is passed through.

In a further advantageous embodiment, stands out the inhalation therapy device according to the invention thereby that the control of the compressor or membrane Aerosol generator depending on the output signal of the Magnetic field sensor takes place.

In a further advantageous embodiment, stands out the inhalation therapy device according to the invention thereby from that the breathing air guidance device of the Breathing air measuring device at one end on one Connection nipple of the inhalation therapy nebulizer can be plugged on is and a mouthpiece is provided at its other end.

In the following the invention is based on a Embodiment described in more detail. This becomes reference taken on the figures in which shows:

FIG. 1 shows an inhalation therapy device according to the invention with a respiratory flow measuring device;

Fig. 2 shows a first embodiment of a respiratory flow measuring device according to the invention in cross section and in a perspective detail view;

Fig. 3 shows a second embodiment of a respiratory flow measuring device according to the invention in cross section and in a perspective detail view;

Fig. 4 shows a third embodiment of a respiratory flow measuring device according to the invention in cross section and in a perspective detail view and

Fig. 5 shows a further embodiment of an inhalation therapy device according to the invention with a respiratory flow measuring device.

The following is an embodiment of the invention the area of therapeutic inhalation nebulizers described. These devices may a. on that the patient's breathing is reliably and precisely recorded, so that nebulizing the therapeutically active substance can be controlled and optimized according to breathing. The reliability and accuracy of the measured values play a role important role in this area. The invention However, respiratory flow measuring device is also in the diagnostic Can be used in areas such as stress tests To capture the patient's breathing accurately.

In the exemplary embodiment shown in FIG. 1, the respiratory flow measuring device according to the invention is used on an inhalation therapy nebulizer 1 , with which an aerosol is generated which the patient can breathe in from the inhalation therapy nebulizer via a mouthpiece 2 .

The mouthpiece 2 is usually attached to a connecting piece 3 . To nebulize the therapeutic substance, the nebulizer in the exemplary embodiment shown is supplied with compressed air via a compressed air line 4 , which air is provided by a compressor 5 . In conventional devices, the compressor 5 continuously delivers compressed air after switching on, the supply to the nebulizer 1 being controlled manually, for example with the aid of a manually operable valve.

The breathing air measuring device according to the invention is arranged between the connection piece 3 of the inhalation therapy nebuliser 1 and the mouthpiece 2 . For this purpose, the device according to the invention for measuring breathing air flow parameters comprises a breathing air guiding device 10 , here embodied in the form of a short tube piece, the end cross sections of which are adapted to the mouthpiece 2 or the outlet nozzle 3 of the inhalation nebulizer 1 .

Of course, the breathing air guiding device 10 can be formed as part of the connecting piece 3 or the mouthpiece 2 or can even be designed integrally with both components of the inhalation therapy nebulizer shown.

According to the invention, a magnetic field sensor 11 is attached to the short pipe section 10 and is detachably connected to the pipe section. In the present case, the attachment is a band 12 , which is placed around the pipe section and with which a secure but detachable attachment of the magnetic field sensor 11 is achieved. The band 12 preferably has a closure so that the band can be opened and closed again.

Furthermore, a permanent magnet 13 is fastened to the tube piece 10 in order to generate a magnetic field which surrounds the magnetic field sensor 11 . As shown in Fig. 1, the permanent magnet 13 can be permanently attached to the pipe section 10 if it is ensured that during cleaning and sterilization / autoclaving, impairment of the permanent magnet is excluded or remains within an acceptable range. If an element for generating a magnetic field is used which is subject to restrictions with regard to cleaning and sterilizing / autoclaving, the device 13 generating the magnetic field can also be detachably attached to the breathing air guiding device 10 . Basically, tape 12 , which was described in connection with magnetic field sensor 11 , is suitable for this.

The breathing air guiding device 10 preferably has a flat recess or another positioning device into which the magnetic field sensor 11 can be inserted, so that the position of the components is defined in a simple manner.

An output signal of the magnetic field sensor 11 can be used in different ways. In the exemplary embodiment described here, the output signal is supplied to the compressor 5 , so that, depending on the output signal of the magnetic field sensor 11 representing the patient's breathing, the supply of compressed air to the nebulizer 1 is controlled by a control device 51 , which is preferably arranged in the compressor 5 becomes. The control device 51 can be designed such that compressed air is supplied to the nebulizer 1 when the patient inhales, and thus the substance stored in the nebuliser is atomized, while the supply of compressed air and the nebulization of the substance does not take place in the exhalation phase. Other control processes, evaluations and uses are conceivable and can be carried out on the basis of the output signal of the magnetic field sensor 11 .

As shown in FIG. 2, a magnetic field sensor 11 and a magnetic field generating device 13 are arranged on the outside of the breathing air guide tube 10 such that the magnetic field surrounds the magnetic field sensor. A permanent magnet is provided as the magnetic field generating device 13 in the embodiment shown here. The magnetic field sensor 11 is, for example, a Hall sensor, which emits a changing output signal whenever the magnetic field surrounding it changes. Without further measures, the magnetic field of the permanent magnet is constant, so that the Hall sensor emits a constant output signal.

According to the invention, a device 14 , which changes the magnetic field of the magnetic field generating device acting on the sensor, is arranged inside the breathing air guiding device 10 . The exemplary embodiment shown here is a flat ferromagnetic strip 14 which is arranged transversely to the direction of flow of the breathing air in the breathing air guidance device of the respiratory flow measuring device according to the invention.

The strip 14 shown in Fig. 2 is suspended resiliently and shown in its rest position R in Fig. 2. If the patient breathes in through the respiratory flow measuring device according to the invention (arrow A), the strip 14 is deflected accordingly and thus influences the magnetic field surrounding the magnetic field sensor such that the sensor emits a corresponding signal. When the patient has completed the inhalation phase, the strip 14 is moved back into its rest position R due to the resilient suspension. When the patient exhales, the strip is deflected in the opposite direction and at the end of the exhalation phase, the strip 14 returns to its rest position R. The change in the magnetic field associated with the back and forth movement of the strip leads to an evaluable output signal of the magnetic field sensor 11 , in the present example the Hall sensor. The size of the breathing air flow (intensity), its direction and the time profile can be recovered from the output signal of the sensor 11 , since the influence of the magnetic field by the ferromagnetic strip 14 always closely follows the patient's breathing. Particularly good results can be achieved if, as already mentioned above, a Hall sensor is used.

The resilient strip 14 is held at one end in a base 15 inside the breathing air guiding device 10 . This mounting can take place in that a slot is provided in the base 15 , into which the resilient strip 14 is inserted. The base 15 is preferably formed in one piece with the wall of the breathing air guiding device 10 . In the right representation of FIG. 2, the holder of the resilient strip 14 in the base 15 is shown in a detail in a perspective view.

FIG. 3 shows an exemplary embodiment in which the device 14 that changes the magnetic field is implemented in the form of a strip that includes a first section 14 a that runs perpendicular to the flow direction A of the breathing air that is guided through the breathing air guide device 11 . Furthermore, the strip 14 has a second section 14 b which extends at an angle to the first section 14 a and is arranged such that it is close to the sensor 11 .

In the exemplary embodiment according to FIG. 3, too, the breathing air of the patient guided through the breathing air guiding device 10 has the effect that the resilient strip 14, as an influencing device, has a changing influence on the magnetic field that surrounds the magnetic field sensor 11 and that is provided by the magnetic field generating device 13 . The arrangement of the angled section 14 b in the vicinity of the magnetic field sensor 11 , which is preferably designed as a Hall sensor, results in a particularly clear and precise measurement signal.

Also in the embodiment according to FIG. 3, the resilient strip 14 is disposed in a socket 15 which is formed integrally with the wall of the breathing air-guiding device 10. In the illustration on the right side of FIG. 3, the arrangement of the resilient strip 14 in the base 15 is shown in a cut-out illustration.

In the exemplary embodiment according to FIG. 4, which corresponds to the exemplary embodiment according to FIG. 2 with regard to the magnetic field generating device 13 and the influencing device 14 , the magnetic field sensor 11 is arranged in a housing 16 which is arranged on the outside of the breathing air guiding device 10 . For this purpose, the breathing air guiding device 10 has on its outside a positioning device 17 , for example a recess into which the housing 16 can be inserted, inserted or arranged in some other way. The dimensioning of the recess 17 and the housing 16 can take place in such a way that the housing 16 is additionally securely fixed on the outside of the breathing air guiding device 10 by the insertion or insertion. As a result, the magnetic field sensor 11 is also securely and securely fixed to the breathing air guidance device 10 . It is obvious that the design of the housing 16 and the positioning device 17 can also be applied to the magnetic field generating device 13 . Likewise, in the embodiment with a housing for the magnetic field sensor and / or a housing for the magnetic field generating device 13 , a magnetic field influencing device 14 can also be used, which includes an angled section 14 b, as shown in FIG. 3.

In the foreground according to the invention is the fact that the magnetic field sensor 11 can be separated from the breathing air guiding device 10 , so that the breathing air guiding device 10 with the influencing device 14 and optionally the magnetic field generating device 13 can be subjected to thorough cleaning. The unit comprising breathing air guiding device 10 , magnetic field generating device 13 and influencing device 14 can also be autoclaved, since the design of these elements in a suitably resistant form is generally unproblematic. Since the magnetic field sensor 11 is placed on the outside of the breathing air guiding device 10 , the need for cleaning to the extent required for the breathing air guiding device 10 and all elements permanently connected to it is not necessary here. The unproblematic transferability of the detachable design to the magnetic field generating device 13 also allows the use of sensitive components at this point in the respiratory flow measuring device according to the invention. Only the device 14 that influences the magnet must necessarily be designed to be robust.

It should also be noted that the described here Refinements, the arrangement of the magnetic field sensor and a magnetic field generating device always takes place in such a way that these two components towards the respiratory flow lie one behind the other and the one influencing the magnetic field Facilitates itself when deflected by the air flow away from one of the two components and towards the other of the two components. This will create a Output signal caused at the magnetic field sensor, the one Statement about the direction of flow and thus about the The patient's breathing phase allowed.

The following is another embodiment of the Invention also from the field of therapeutic Inhalation nebulizer described.

In the example shown in Fig. 5 embodiment, the present invention is used in a Attemflussmesvorrichtung Inhalationstherapievernebler 100, with which an aerosol is generated, which the patient can breathe through a mouthpiece 102 from the Inhalationstherapievernebler 100.

In this exemplary embodiment, a membrane aerosol generator 103 is used to nebulize the therapeutic substance, in which a vibrating porous membrane 104 nebulizes the medicament stored in a storage container 105 , which is on one side of the membrane 104 , into a nebulizing space 106 . The membrane 104 , which is preferably made to vibrate piezoelectrically, is controlled with the aid of a control device 110 , which for this purpose is connected to a piezo crystal 107 which is arranged on the membrane 104 . By actuating the piezo oscillator 107 , the membrane 104 connected to the piezo oscillator is set in vibration, so that the medicament stored in the storage container 105 is atomized into the nebulization chamber 106 through the openings of the porous membrane 104 . From there, the patient inhales the aerosol.

The breathing air flows through the inhalation therapy nebulizer 100 , the breathing air being supplied to the inside of the inhalation therapy nebulizer 100 when breathing in from outside through breathing air channels 108 . When the patient exhales into the inhalation therapy nebulizer 100 , the air exhales through the channels 108 into the environment.

According to the invention, an influencing device 114 is arranged in the inhalation therapy nebulizer 100 and is moved by the breathing air when the patient inhales or exhales. The bracket is carried out in this embodiment with the help of a base 115 which is integrally formed with the mouthpiece 102 and which the fastening device 114 z. B. in a slot 116 . According to the invention, a magnetic field sensor 111 and a permanent magnet 113 are arranged outside the inhalation therapy nebulizer 100 . In this exemplary embodiment, both the magnetic field sensor 111 and the permanent magnet 113 are accommodated in a housing 109 in which the control device 110 is also arranged. It is crucial that the magnetic field sensor 111 is arranged in the housing 109 . The inhalation therapy nebulizer 100 can be removed from the housing 109 , which can be regarded as a base unit, e.g. B. be separated for cleaning. During use, however, the inhalation nebulizer 100 is connected to the housing 109 so that the control signals are led from the control unit 110 to the membrane aerosol generator 103 , 104 , 107 . In this case, the magnetic field sensor 111 , the permanent magnet 113 and the influencing element 114 are arranged in relation to one another according to the invention, so that the inhalation or exhalation and the movement of the influencing element 114 caused thereby results in a magnetic field that changes from the perspective of the magnetic field sensor 111 . The output signal of the magnetic field sensor 111 is fed to the control unit 110 which, depending on the magnetic field sensor output signal, outputs the control signal to the membrane aerosol generator 103 , 104 , 107 .

In the second exemplary embodiment described here, the breathing air guidance device is formed by the mouthpiece 102 of the inhalation therapy nebulizer 100 . However, the magnetic field sensor 111 , the permanent magnet 113 and the influencing element 114 can also be arranged in the region of the channels 108 , so that in this case the breathing air guidance device is implemented by one of the channels 108 . The shape of the housing 109 is then to be adapted accordingly so that the arrangement of the three components 111 , 113 and 114 according to the invention is given.

Although an influencing device 114 with an angled section is shown in FIG. 5 in the second exemplary embodiment, all of the previously described designs of the influencing device can also be used in this exemplary embodiment.

The positioning of the magnetic field sensor 111 and the permanent magnet 113 on the one hand and the influencing device 114 on the other hand takes place in the second exemplary embodiment in that the housing 109 is adapted to the inhalation therapy nebulizer 100 in terms of shape and accommodates the inhalation therapy nebulizer 100 as a holder. Appropriate shaping achieves a fixation that is safe for use while at the same time reliably positioning the central elements 111 , 113 and 114 according to the invention.

The control device 110 is preferably designed such that the nebulization of the medicament by the membrane aerosol generator 103 , 104 , 107 is interrupted when the patient is not breathing or exhaling into the inhalation therapy nebulizer 100 . If the control device 110 determines on the basis of the output signal of the magnetic field sensor 111 that the patient is breathing in, the control device 110 emits a control signal to the membrane aerosol generator 103 , 104 , 107 , so that an aerosol is generated and made available in the nebulization room 106 .

In another embodiment, the control device 110 can be designed such that the control device 110 emits a control signal to the membrane nebulizer 103 , 104 , 107 if the patient is not breathing or inhaling through the inhalation therapy nebulizer 100 . It is thereby achieved that an aerosol is also provided in the inhalation therapy nebulizer 100 during rest phases, which the patient inhales in the form of an aerosol bolus at the beginning of the inhalation phase.

As from the description of the two exemplary embodiments evident, it is for the invention Respiratory flow measuring device is not critical in which way the aerosol is generated. The first embodiment refers to an inhalation therapy nebulizer with a Compressed air operated aerosol generator, e.g. Legs Nebulizer nozzle, while the second embodiment one Includes membrane aerosol generator. The invention Respiratory flow measuring device can also be used together with a Ultrasonic aerosol generator can be used.

For the use of the respiratory flow measuring device according to the invention it is also not critical whether the aerosol generator is controllable is or is controlled. For the output signal of the Magnetic field sensors offer numerous evaluation options as part of an aerosol therapy that is independent of one Control of aerosol generation are. However, in particular Further possibilities with controllable aerosol generators to improve the therapeutic application of an aerosol given. Nevertheless, independence shows that the respiratory flow measuring device according to the invention also in others Application areas can be used sensibly.

Claims (29)

1. Respiratory flow measuring device with
a breathing air guidance device ( 10 ; 102 ) through which the breathing air of a patient whose respiratory flow is to be measured can be guided inside,
a magnetic field sensor ( 11 ; 111 ) which emits an output signal when the magnetic field surrounding it changes and which is detachably arranged on the outside of the breathing air guidance device ( 10 ; 102 ),
a magnetic field generating means (13; 113) with respect to the magnetic field sensor (11; 111) on the breathing air-guiding device (10; 102) is arranged such that the magnetic field generating means (13; 113) magnetic field generated the magnetic field sensor (11 ; 111 ) surrounds, and
a magnetic field changing influencing means (14; 114) with respect to the magnetic field sensor (11; 111) and magnetic field generating means (13; 113) is arranged such that a spatial displacement of the influencing device (14; 114) a change of the magnetic field sensor surrounding magnetic field and which is arranged and held in the interior of the breathing air guidance device ( 10 ; 111 ) in such a way that it is moved by a breathing air flow guided through the breathing air guidance device at least to such an extent that the changing influencing of the magnetic field caused thereby generates an output signal of the magnetic field sensor ( 11 ; 111 ). 2. Respiratory flow measuring device according to claim 1, characterized in that the influencing device ( 14 ; 114 ) is fixed relative to the breathing air guiding device ( 10 ; 102 ) in such a way that the movement of the influencing device ( 14 ; 114 ) takes place around a rest position (R). 3. Respiratory flow measuring device according to claim 2, characterized in that the influencing device ( 14 ; 114 ) is resiliently fixed relative to the breathing air guiding device ( 10 ; 102 ), so that it automatically returns to the rest position (R) when no breathing air flow acts on it. 4. Respiratory flow measuring device according to one of the preceding claims, characterized in that the influencing device ( 14 ; 114 ) is strip-shaped. 5. Respiratory flow measuring device according to one of the preceding claims, characterized in that the influencing device ( 14 ; 114 ) has a first section ( 14 a; 114 a) which is essentially transverse to the flow direction (A) of the through the breathing air guide device ( 10 ; 102 ) guided breathing air flow is arranged, and comprises a second section ( 14 b; 114 b) which is angled to the first section ( 14 a; 144 b). 6. Respiratory flow measuring device according to claim 5, characterized in that the angled second section ( 14 b; 114 b) of the influencing device ( 14 ; 114 ) is arranged in spatial proximity to the magnetic field sensor ( 11 ; 111 ). 7. Respiratory flow measuring device according to claim 5, characterized in that with resilient mounting of the influencing device ( 14 ) related to a rest position (R) in the breathing air guiding device, the angled second section ( 14 b; 114 b) of the influencing device ( 14 ; 114 ) in spatial Proximity to the magnetic field sensor ( 11 ; 111 ) is arranged when the influencing device ( 14 ; 114 ) is in the rest position (R). 8. Respiratory flow measuring device according to claim 7, characterized in that the angled second section ( 14 b; 114 b) of the influencing device ( 14 ; 114 ) is arranged opposite the magnetic field sensor ( 11 ; 111 ) when the influencing device ( 14 ; 114 ) is in the rest position. 9. Respiratory flow measuring device according to one of the preceding claims, characterized in that the breathing air guide device is a pipe section ( 10 ). 10. Breathing air measuring device according to one of the preceding claims 1 to 8, characterized in that the breathing air guiding device is a mouthpiece ( 102 ). 11. Respiratory flow measuring device according to one of the preceding claims, characterized in that the magnetic field sensor ( 11 ; 111 ) is a Hall sensor. 12. Respiratory flow measuring device according to one of the preceding claims, characterized in that the breathing air guiding device ( 10 ; 102 ) has a first positioning device ( 17 ; 109 ) on the outside for the gastric field sensor ( 11 ; 111 ). 13. Respiratory flow measuring device according to claim 12, characterized in that the first positioning device ( 17 ) is a flat recess which is adapted to the dimensions of the magnetic field sensor ( 11 ). 14. The respiratory flow measuring device according to claim 12, characterized in that the first positioning device ( 102 ) is a housing ( 109 ) adapted to the shape and dimensions of an inhalation therapy nebuliser ( 100 ). 15. Respiratory flow measuring device according to one of the preceding claims, characterized in that the magnetic field sensor ( 11 ; 111 ) is arranged in a first housing ( 16 ; 109 ) which is detachably arranged on the breathing air guidance device ( 10 ; 102 ). 16. Respiratory flow measuring device according to claim 15, characterized in that the breathing air guiding device ( 10 ; 102 ) has a second positioning device ( 17 ; 109 ) for the first housing ( 16 ; 109 ) on the outside. 17. The respiratory flow measuring device according to claim 16, characterized in that the second positioning device ( 17 ) is a flat recess ( 17 ) adapted to the dimensions of the first housing ( 16 ). 18. Respiratory flow measuring device according to one of the preceding claims, characterized in that the device ( 13 ; 113 ) generating the magnetic field is a permanent magnet. 19. Respiratory flow measuring device according to one of the preceding claims, characterized in that the magnetic field generating device ( 13 ; 113 ) can be detached from the breathing air guiding device ( 10 ). 20. The respiratory flow measuring device according to claim 19, characterized in that the breathing air guiding device ( 10 ; 102 ) has a third positioning device ( 17 ; 109 ) on the outside for the magnetic field generating device ( 13 , 113 ). 21. The respiratory flow measuring device according to claim 20, characterized in that the third positioning device is a flat recess adapted to the dimensions of the magnetic field generating device ( 13 ). 22. Respiratory flow measuring device according to one of claims 1 to 16, characterized in that the magnetic field generating device ( 13 ) is arranged in a second housing, that is detachably arranged on the breathing air guiding device ( 10 ). 23. The respiratory flow measuring device according to claim 22, characterized in that the breathing air guiding device ( 10 ) has a fourth positioning device ( 17 ) on the outside for the second housing ( 16 ). 24. Respiratory flow measuring device according to claim 23, characterized in that the fourth positioning device is a flat recess ( 17 ) adapted to the dimensions of the second housing ( 16 ). 25. Inhalation therapy device with
a compressor ( 5 ) for providing a compressed gas, preferably air,
an inhalation therapy nebulizer ( 1 ), to which the compressed gas for nebulizing a substance stored in the inhalation therapy nebulizer ( 1 ) can be supplied by the compressor ( 5 ), and
A respiratory flow measuring device according to one of claims 1 to 24, which is arranged on the inhalation therapy nebulizer ( 1 ) in such a way that the user's breathing air is passed through the breathing air guiding device ( 10 ). 26. Inhalation therapy device according to claim 25, characterized in that the control of the compressor ( 5 ) takes place in dependence on an output signal of the magnetic field sensor ( 11 ). 27. Inhalation therapy device according to claim 25 or 26, characterized in that the breathing air guiding device ( 10 ) of the breathing air measuring device can be plugged on at one end onto a connecting piece ( 3 ) of the inhalation therapy nebulizer ( 1 ) and a mouthpiece ( 2 ) is provided at its other end. 28. Inhalation therapy device with
an inhalation therapy nebulizer ( 100 ), in which a membrane aerosol generator ( 103 , 104 , 107 ) is arranged for nebulizing a liquid to be atomized,
a control device ( 110 ) for controlling the membrane aerosol generator ( 103 , 104 , 107 ) and
A respiratory flow measuring device according to one of claims 1 to 24, which is arranged on the inhalation therapy nebulizer ( 1 ) in such a way that the user's breathing air is passed through the breathing air guiding device ( 102 ). 29. Inhalation therapy device according to claim 28, characterized in that the actuation of the membrane aerosol generator ( 103 , 104 , 107 ) takes place as a function of an output signal of the magnetic field sensor ( 111 ).