DE2227067A1 - SPIROMETER AND METHOD OF MONITORING THE FLOW OF A FLOWING MEDIUM - Google Patents

Description

'Case 682-6437

Sandoz AG.

2.6.1972 Gu / gm Basel

Patent attorneys

Dipf.-Jn.-3. P. Throws

Dr, V. Sch.rt3f. ^J -Kcv / arrik

Dipl .- !, ·. £ ·. C iinnnaribcrg

Dr. P. Weiche: », Lv. D. Gudel

6 Frankfurt / M., Gr.Es.'isn'wiiiVi. Ϋ́ιΓ.39.

Spirometer and method for monitoring the flow of a flowing medium

The invention relates to a spirometer , in particular an electronic spirometer, and to a method for monitoring the flow of a flowing medium.

The term spirometer is understood to mean a device with which one can determine the flow parameters of a the flowing medium can be monitored, in particular a device suitable for use in hospitals,

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with which one can measure respiratory parameters, such as the maximum Breathing capacity, peak breathing behavior, the volume of exhalation during exertion and the total volume on exhalation.

The inventive electronic spirometer is characterized by a thermistor via which the
The flow of the measuring medium to be monitored is passed through a circuit for adjusting the temperature of the thermistor to an increased working temperature, by a sampling circuit for sampling a drop in the working temperature of the thermistor as a result of the flow of the flowing medium passed through it and the resulting decrease in its Resistance, by a compensation circuit to compensate the thermistor against the temperature drop and to keep its temperature constant at the working temperature, as well as by monitoring means for monitoring the degree of compensation of the thermistor by the compensation circuit depending on the flow of the flowing medium.

The invention is also directed to a method for monitoring the flow of a flowing medium,
which is characterized by the fact that one
Regulates the thermistor to an increased working temperature, guides the flowing medium over the thermistor,
senses a possible drop in temperature at the thermistor as a result of the decrease in its resistance caused by the medium flowing over it, compensates for the temperature drop in the thermistor and its

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Keeps the temperature constant at the working temperature and those necessary to maintain the temperature of the thermistor at a constant working temperature Degree of compensation monitored as a function of the flow of the flowing medium «,

The circuit for temperature adjustment is preferably designed so that the thermistor temperature to an elevated working ™ by Joul ^'8 is shear heating controlled by applying a potential difference across the thermistor. The compensation circuit 3O is also preferably designed so that a temperature drop on the thermistor is compensated for while maintaining a constant working temperature by means of Joule heating by applying a potential difference across the thermistor. In one embodiment of the inventive spirometer, the compensation circuit consists of a differential amplifier circuit, through which a sampled decrease in the resistance of the thermistor can be received as a decrease in the input potential difference over the input signals of the amplifier, and through which the thermistor over an amplification of the input potential difference and using the increased potential difference can be compensated via the thermistor. The sampling circuit preferably consists of a resistance bridge circuit in which a thermistor is located in one arm, and of the signal inputs of the differential amplifier, the inputs being connected via a first pair of opposite connection points of the bridge circuit and the signal output of the differential amplifier so

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is implied that a potential difference over a second pair of opposite connection points of the bridge circuit applied to compensate for the thermistor will. The differential amplifier circuit may include a direct feedback loop. Most comfortable the differential amplifier circuit consists of a differential amplifier coupled to an additional amplifier, for example an emitter amplifier, the additional amplifier being the output of the differential amplifier reinforced.

The thermistor is preferably set to an elevated working temperature between 150 and 250 ° C, in particular 180 and 220 ° C, regulated.

Any device can be used as the monitoring means with which one can track the degree of compensation through the compensation circuit, for example a voltmeter for monitoring a potential, which preferably flows in suitable units Medium is calibrated. ~ .- ,,;,: ■

An embodiment of the invention is explained in more detail with reference to the drawing, which shows a circuit diagram of this Spirometer shows.

The spirometer consists of a thermistor R, which is inserted into a sampling circuit in the form of a Kid Resistance bridge circuit 13 is arranged, which is connected to inputs is coupled to a differential amplifier circuit,

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a compensation circuit in the form of a differential "· ■ amplifier circuit 11, as well as in Ueberwachungsmitteln: Form a voltmeter 16. The Differentialverstärker- ^': circuit 11 is simultaneously used for tem-"^"·; peratureinregelung -.'"'-' ■

The ^{resistor bridge circuit 13} consists of four resistors or sets of resistors R., R_, R, and R_,

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as well as R, which are all arranged between the connection points J ₁ , J_, J ₂ and J. The set of resistors R- and R "is connected in series. _{Resistor R 4.} can be changed and the cons

stand R_ represents the thermistor. The connection point J. the resistor bridge is grounded.

The differential amplifier circuit 11 consists of a differential amplifier 15 which is connected to an additional amplifier in the form of an emitter amplifier 17. The differential amplifier circuit 11 has connection terminals T-, T, T ₃ and T., and a series resistor R- and a diode 12 are also provided to ensure that the current from the differential amplifier arrives positively. The polar direction of the applied force (15 V) is also shown in the figure.

The differential amplifier is provided with a direct feedback circuit 18 in which a resistor R ₁₀ is located between the signal output of the emitter amplifier 17 and the negative signal input of the

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Differential amplifier 15 is located. The reinforcement through the differential amplifier circuit 11 is of course suspended from resistors R, R, R and R. away.

The signal inputs of the differential amplifier 15 are connected via a first pair of opposite Brückenver-: ■ connected · connection points J and J _0th The signal output of the emitter amplifier is connected to the connection point J_ of the bridge circuit and to the voltmeter 16.

The method for monitoring a gas flow by means of of the spirometer of the embodiment described above is explained in more detail below:

When power is supplied to the differential amplifier circuit via the terminals T, T_, T and T, a minimum limited output passed to junction J of the bridge circuit, and. even if the bridge is balanced and there is no potential difference between the signal inputs of the differential amplifier consists, the differential amplifier circuit acts overall as a circuit for temperature control. Because the connection point J of the bridge circuit is grounded is, an output potential difference becomes at the second pair of opposite connection points J and J of the bridge created.

The thermistor is originally at room temperature,

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and its resistance depends to a large extent on temperature so that the bridge is not balanced at the beginning, i.e. the resistors R_ and R. are opposite the resistors R_, R_. and R_ not matched. In this way, an output potential difference is formed between the first pair of connection points J .. and J. from which is received by the differential amplifier circuit 1-1, and which in amplified form for Increase in the output potential difference over the second pair of connection points J and J and for compensation of the thermistor is used. The gain of the caused by increasing the output potential difference Current causes the temperature of the thermistor to rise 'and thus also the resistance until the bridge circuit is balanced, whereupon the thermistor assumes its working temperature. By adjusting the resistance of the variable resistance R can of course be

borrowed the working temperature of the thermistor within certain Change boundaries.

When the bridge circuit is balanced, i.e. when the thermistor has reached its working temperature, the Increase the output from the amplifier circuit 11 to the connection point J according to, the working potential difference via the second pair of opposite connection points of the bridge and the .by the bridge flowing current then remain constant for the respective time. As can be seen, there are temperature controls of the thermistor and reaching the working condition of the entire circuit are coordinated and proceed quickly. As soon as the working condition is reached, leaves

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use the spirometer to monitor the gas flow. Monitoring is carried out by directing the gas flow over the thermistor. Since the thermistor is at a higher working temperature / normally between 180 and 22Q ⁰ Q., a gas flow with a lower temperature through the thermistor leads to a temperature drop and thus to a lower kiderstand of the Thermistor, which is noticeable by an unbalanced bridge. As mentioned above, however, the presence of an unbalanced bridge in the form of a potential difference across the first pair of opposing junctions J. and J is tapped by the bridge and the differential amplifier circuit, and the bridge is immediately compensated by the differential amplifier current. In practice, the temperature of the thermistor thus remains constant at its working temperature, the potential difference applied across the second pair of connection points varying as a function of the gas flow. In this way, the gas flow can be monitored continuously via the voltmeter 16 which is connected to the output of the differential amplifier circuit.

Although the working temperature of the thermistor can be of the order of 200 ⁰ C, have small changes in the ambient temperature only an insignificant influence on the accuracy of the parameters of the monitored gas flow. Because of the high working temperatures, the thermistor reacts within a shorter time. The variable resistance R ^ also enables identical results to be obtained on the gas flow using different thermistors.

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Claims (18)

Protective resp.
Claims ί l.j Electronic spirometer, characterized by a Thermistor, through which the flow of the flowing medium to be monitored is passed through a circuit to regulate the temperature of the thermistor to an increased working temperature, by a sampling circuit for Sensing a drop in the working temperature of the thermistor due to the flow of the thermistor passed over it flowing medium and the resulting decrease in its resistance, through a compensation circuit for compensation of the thermistor against the temperature drop and for Keeping its temperature constant at the working temperature, and by monitoring means for monitoring the degree of compensation of the thermistor by the compensation circuit depending on the flow of the flowing medium. 2. Electronic spirometer according to claim 1, characterized in that the thermistor is regulated to an increased working temperature by means of Joul ¹ shear heating by applying a potential difference across the thermistor. 3. Electronic spirometer according to one of the preceding claims, characterized in that the compensation circuit is designed so that a temperature drop across the thermistor while maintaining a constant working temperature is compensated by means of Joule heating by applying a potential difference across the thermistor. 209881/0421 4. Electronic spirometer according to claim 3, characterized characterized in that the compensation circuit consists of a differential amplifier circuit through which a The sensed decrease in the resistance of the thermistor can be received as a decrease in the input potential difference via the input signals of the amplifier, and through which the thermistor via an amplification of the input potentialdif f'erenz and using the amplified potential difference can be compensated across the thermistor. 5. Electronic spirometer according to claim 4, characterized characterized in that the sampling circuit consists of a resistance bridge circuit in which one arm has a Thermistor lies, and from the signal inputs of the differential amplifier, the inputs via a first pair of opposite one another Connection points of the bridge circuit are connected, and wherein the signal output of the differential amplifier is connected so that there is a potential difference across a second pair of opposing connection points the bridge circuit is applied to compensate for the thermistor. 6. Electronic spirometer according to claim 4 or 5,
characterized in that the differential amplifier circuit includes a direct feedback loop. 7. Electronic spirometer according to one of claims 4 to 6, characterized in that the differential amplifier circuit consists of a differential amplifier coupled to an additional amplifier, the 209881/0421 Auxiliary amplifier amplifies the output of the differential amplifier. 8. Electronic spirometer according to claim 7, characterized characterized in that the additional amplifier is an emitter amplifier. · 9. Electronic spirometer according to one of the preceding claims, characterized in that the Circuit for regulating the temperature of the thermistor to increased working temperatures between 150 and 25O ° C regulates. 10. An electronic spirometer according to claim 9, characterized in that the circuit for adjusting the temperature adjusts the thermistor to an elevated working temperature zv ¹ / een 180 and 22O ° C. 11. Electronic spirometer according to one of the preceding claims, characterized in that the Monitoring means from a voltmeter for monitoring the degree of compensation of the thermistor by the compensation means exist, and zv / ar measured as potential, 12. Method for monitoring the flow of a flowing medium, characterized in that a thermistor is adjusted to an increased working temperature, the flowing medium conducts over the thermistor, a possible temperature drop at the thermistor as a result who senses the decrease in resistance caused by the flowing medium flowing over him, the temperature 209881/0421 temperature drop of the thermistor compensates and keeps its temperature constant at the working temperature, and those necessary to maintain the temperature of the thermistor at a constant working temperature Degree of compensation monitored as a function of the flow of the flowing medium. 13. The method according to claim 12, characterized in that that the increased working temperature of the thermistor by means of Joule heating by applying a potential difference adjusted via the thermistor. 14. The method according to claim 1: 2 or I3, characterized ' characterized in that the drop in the temperature of the thermistor by means of Joule heating by applying compensated for a potential difference across the thermistor » 15. The method according to claim 14, characterized in that that one can see the drop in the resistance of the thermistor as a drop in the potential difference between the signal inputs a differential amplifier circuit taps the potential difference through the differential amplifier circuit reinforced and the reinforced potential difference across the thermistor to compensate for the thermistor. 16. The method of claim 12 to 15, characterized in that one adjusts the thermistor to an elevated working temperature between 150 and 25O ⁰ C. 209881/0421 17. The method according to claim 16, characterized in that the thermistor is adjusted to an increased working temperature between 180 and 220 ⁰ C. 18. The method according to any one of .Ansprüche 13 to "17, characterized in that the degree of compensation of the thermistor is monitored by compensation means in potential values. Dtr patent attorney 209881/0421 Le first page