DE2812093A1 - Rhino-manometer for air flow - generates signal proportional to square of current and incorporates back pressure tubes - Google Patents

Abstract

The rhinomanometer measures the air flow through the nose and the transnasal pressure. A measuring device generates a signal proportional to the square of the air current, and incorporates one or more back-pressure tubes (20, 21) to determine the dynamic pressure. These tubes are mounted axially in a tubular casing (1) of larger dia. through which the respiratory air flows for the nose. An electronic circuit generates the quotient from the transnasl pressure and the square of the air current, this being indicated or recorded while breathing.

Description

Rhinomanometer with resistance display

The present invention relates to a rhinomanometer according to the preamble of claim 1.

In rhinology, a rhinomanometer is used to measure the flow resistance measured from the nose. To do this, the air flow V is through the nose and the transnasal Pressure ap recorded by measurement.

The previously known rhinomanometers were used to measure the air flow V the following measuring arrangements are used: (1) The air flow V is caused by a flow resistance which consists of a pipe with screens, screens or lamellas. The one with it The pressure drop that occurs is proportional to the air flow V. The pressure is measured with metal diaphragms whose deformation is detected electromechanically or inductively will. (2) Another known method is the airflow from the nose passed through a tube about 1 cm in diameter. In the pipe there are hot wire or hot film probes that measure the flow velocity. Through a calibration measurement the air flow V is determined from this. The method has the advantage that that pipe represents a smaller flow resistance.

This results in lower requirements for the tightness of the Nose attachments or breathing masks. The disadvantage of Measuring arrangement lies in the fact that between inhalation and exhalation there is no change in sign in the electronic Signal occurs and that the known probes are too sensitive for clinical use are. Both measuring arrangements described provide signals proportional to the air flow V.

As a rule, the electronic signals of transnasal pressure 4p and the air flow V are given on an x-y recorder. There in the nose a turbulent one Flow is present, the x-y plotter curve shows the following quadratic during breathing Relationship between the transnasal pressure and the air flow: a p V2. From it it follows that the flow resistance of the nose R = is not constant. Against it is the quotient ~ # p / V2 is a constant value. With the previously known rhinomanometers is made from the non-linear x-y plotter curve graphically or with an analog computer the constant quotient p / V2 is determined. There is also a method used in that from the x-y plotter curve the air flow V15 at the fixed transnasal Pressure ap = 15 mmH20 is specified. The state of the art can be summarized: The previous rhinomanometers require an x-y recorder, which is a non-linear one Curve delivers. The measured variable 4p / V 'and / or V15, which characterizes the condition of the nose, can be determined graphically or by calculation.

The present invention is based on the object of a rhinomanometer indicate which one on the one hand provides a linear x-y plotter curve and on the other hand is also able to record the measured quantities without using the x-y recorder 4 to display p / VC and / or V15. The flow resistance of the measuring arrangement should be small be.

This object is achieved according to the invention by a rhinomanometer with the Features of the characterizing part of claim 1 solved.

The fact that a measuring arrangement is used to determine the air flow which delivers a signal proportional to v2, a linear x-y plotter curve is created, and by means of a dividing circuit, the measured variable 4 p / V 'can also be measured directly without an x-y recorder formed and displayed, whereby V can also be displayed.

15 With the measuring arrangement the dynamic pressure Pv in the air flow measured, which depends on the flow velocity v and the air density: pv = g v2 / 2. The air stream is allowed to pass through a cross-sectional area of known size and thus receives a signal pvs. The advantages achieved with the invention exist especially in the fact that in practice a very simple rhinomanometer without an x-y recorder can be used with at least one display unit for # p / V2 and / or V15.

If you want additional information, you can also use an x-y recorder to be used. The linearity of the x-y plotter curves is usually easier the clinical interpretation is essential. Furthermore, the specified Measuring arrangement by a small flow resistance.

Developments and advantageous refinements of the rhinomanometer according to the invention are characterized in the subclaims.

In the following, exemplary embodiments of the invention are referred to explained in more detail on the drawings.

They show: FIG. 1 a simplified scheme of a rhinomanometer according to FIG an embodiment of the invention; 2 shows a representation of the measuring arrangement with Pitot tubes for measuring Pvs V, as is done with a rhinomanometer according to FIG. 1 can be used; 3 and 4 each further representations of the measuring arrangement with a pitot tube for the rhinomanometer according to Figure 1; Fig. 5 and 6 each one Representation of a measuring arrangement with Venturi tubes for a rhinomanometer according to FIG. 1; Fig.? a circuit principle for the pressure gauges in a capacitance bridge circuit, as it can be used in a Rh inomanometer according to FIG.

In the simplified scheme of the Rhinmanometer in Fig. 1 means 1 a measuring arrangement, for example according to Fig. 2-6, through which the air flow from the nose is directed. For this purpose, a nasal attachment piece 2 or a Not shown breathing mask attached. The measuring arrangement delivers a signal proportionally to V2, which via one or two hoses 3 to the manometer or differential manometer 4 is directed. The manometer or difference manometer can, for example, a Represent capacitance, one electrode of which is designed as a pressure membrane. It The pressure gauges mentioned in patent claim 4 are also possible. The capacity change is proportional to the pressure and it can be achieved, for example, by means of a capacitance bridge circuit 5 according to FIG. 7 can be detected. The transnasal pressure 4p is known by a tube 1 measured in the mouth or contralateral nostril, with the pressure is passed through a hose 3 'to the pressure gauge 4'. The manometer 4 'and the capacitance bridge circuit 5 can be constructed similarly to 4 and 5. Arise at the output of the circuits 5 and 5 ' electrical signals proportional to V2 and zip.

These electrical signals can be sent directly to the pointer instruments 6 and 6 'are given. Furthermore, these electrical signals can be transferred to an x-y recorder7 or an oscilloscope. Furthermore, according to the invention, these given electrical signals to a dividing circuit 8. At the output of the dividing circuit an electrical signal is generated which is proportional to Ap / V2. This electric Signal proportional to ap /; 2 can be switched via switch 9 on pointer instrument 6 are displayed. For linearization can be an unsigned one beforehand logarithmic amplifier can be switched on. The pointer instrument 6 can also be calibrated so that V15 is displayed. There is also a digital display for # p / v2 and / or V15 possible, or these measured variables can be recorded with the switch 10 with the recorder 7 will.

In Fig. 2 is a measuring arrangement 1 with the extension 2 for measurement shown by V. When inhaling, the air pressure pO is measured on the pitot tube 20. In contrast, the static pressure, which is given, is measured on the pitot tube 21 by pO - g v2 / 2.

2 When exhaling, pO + <? V / 2 is measured on the Pitot tube 21 and Pitot tube 20 po. These pressures are applied to the differential manometer via the hoses 3 of FIG 4 headed. The pressure difference during inhalation and exhalation is therefore - S v2 / 2 and + gv2 / 2. Since v is proportional to V, one obtains at the output of the capacitance bridge circuit 5 of Figure 1, an electrical signal proportional to V2. Ideally the pitot tube 20 always shows pO, it can also be omitted. To correct pressure drops and to protect the differential pressure gauge, however, it can also be retained.

Fig. 3 shows a measuring arrangement 1 with the extension 2, wherein for Simplification only the Pitot tube 21 is attached.

Fig. 4 shows a further simplification of the measuring arrangement, which now only consists of the Pitot tube 21, which is a little longer. This pitot tube 21 can be used, for example, to the dynamic pressure in the Limen to measure nasi.

In Fig. 5 a Venturi tube is shown, which as a measuring arrangement 1 serves. The static pressures before and after the constriction are generated with the pipes 21 'and 20' 30 measured and given to the differential manometer 4 with the hoses 3 of FIG.

As is known, this pressure difference is proportional to V2.

With the Venturi tube, there is no sign change in the differential pressure when breathing in and out.

In Fig. 6 a modification of the Venturi tube is shown, wherein the narrowing is replaced by a sharp aperture 30 ~. In contrast to Fig. 5 a sign change occurs here.

In Fig. 7, a suitable capacitance bridge circuit 5 and 5 is shown in FIG. 1 as it is used to detect the pressure signals from the pressure gauges 4 and 4 'can be used. An oscillator 41 generates an RF voltage which is based on the Capacities 42, 42 ', 42 ", and 43 are given, which are part of a not shown Lc-member is. The manometer 5 or 5 'forms a variable capacitance 45, with the change in capacitance is proportional to the pressure or differential pressure. A capacitance diode 44 is used for Compensation for fluctuations in capacity, which are particularly due to the variable Capacity 45 caused by thermal influences. Between 42 and 42 'as well as; 45und 42 ″, the differential voltage is applied to the differential amplifier 50.

The output of 50 is through a phase sensitive Rectifier 51, which is controlled by the oscillator 41, is rectified. The signal from the phase sensitive Rectifier 51 is sent to output 52 via RC element R, C. The output signal is used to compensate for fluctuations in capacity, especially the variable ones Capacitance 45 through amplifier 60 with resistors 61, 61, 61 "and the capacitance 62 with negative feedback in order to control the capacitance diode 44. With the switch 63 you can different time constants can be realized in the negative feedback during the measurement the switch 63 remains open and through the resistor 61 and the capacitance 62 is formed a large time constant. To adjust the zero point before the measurement, the switch 63 is closed, with 61 ', 60 and 62 being a small time constant arises.

Modifications can be made to avoid turbulence, especially when exhaling can be provided in Figures 2, 5 and 6 showing the diameter of the air flow Increase slowly in the Messandordnung 1. This can be done by yourself the diameter of the tubes of the measuring arrangement 1 along the axis # to the outlet end, which is opposite the nasal attachment piece 2, enlarged.

Some ideas of the invention can also be realized, though Measurement arrangements are used that provide a signal proportional signal to the air flow V. In this case, according to the invention, the signal is generated by an electronic circuit squared proportional to the airflow.

Claims (7)

Claims Rhinomanometer with measuring arrangements for measuring the Air flow through the nose and the nasal pressure, that is not possible n z e i c h n e t that a measuring arrangement was used to determine the air flow which generates a signal proportional to the square of the air flow that the Measuring arrangement for determining the air flow from one or more pitot tubes ( 21 and 20 in FIGS. 2, 3 and 4) for determining the dynamic pressure, where the pitot tube or tubes axially in a tubular casing of larger diameter can be attached, through which the breath of the nose flows that through a electronic circuit the quotient of the transnasal pressure and the square of the air flow is formed and displayed and / or written while breathing will. 2. Rhinomanometer with measuring arrangements for measuring the air flow through the nose and transnasal pressure, which is not shown that when using measuring arrangements that produce a signal proportional to the air flow generate, by an electronic circuit, the signal is squared that by another electronic circuit of the quotient of the transnasal pressure and the square of the air flow is formed and displayed during breathing and / or is written. 3. Rhinomanometer according to claim 1 and 2, d a d u r c h g e -k e n n e i n e t that others from the quotient of the transnasal pressure and the Square of the air flow derived variables formed and displayed and / or written will. 4. rhinomanometer according to claim 1, d a d u r c h g e k e n n drawn, that the air flow instead of measuring arrangements with pitot tubes (Fig. 2, 3 and 4) also with measuring arrangements with venturi tubes or similar tubes (Fig. 5 and 6) measured will. 5. Rhinomanometer according to claim 1 and 4, d a d u r c h g e k e n n z e i c h n e t that the pressure measurement of the measuring arrangements for measuring the air flow with capacitive, IC manometers (IC pressure transducer), strain gauges, inductive and piezoelectric manometers. 6. rhinomanometer according to claim 1, 2, 3 and 4, d a d u r c h g e k It is noted that the zero point stabilization when using capacitive pressure gauges takes place with the help of a capacitance diode in negative feedback circuit (Fig.7). 7. Rhinomanometer according to claim 1 and 4, d a d u r c h g e -k e n I would like to point out that to reduce turbulence especially when exhaling the air flow in the diameter is slowly increased, which is achieved by a enlargement the diameter of the measuring arrangement for determining the air flow along the axis is achieved.