DE2628758A1 - Blood pressure measuring apparatus using Korotkow oscillations - has band pass filter, threshold circuit, monostable trigger and rectifier - Google Patents

Abstract

Blood pressure measuring equipment converts to Korotkow oscillations and converts into oscillations which are passed through a band pass filter to a threshold circuit so that when earth oscillation exceeds a given amplitude, a monostable trigger circuit is operated so that the systolic blood pressure is indicated, and the last pulse blocks an indicator for the diastolic blood pressure. The positive and negative half pulses are converted into pulses of the same polarity before the threshold circuit is reached. Between the band pass filter and the threshold circuit is a two way rectifier which has two operational amplifiers each with an inverting and non inverting input followed by an arrangement of resistors and capacitors and a pair of diodes.

Description

State of the art

The invention is based on a method according to the preamble of the main claim.

An automatically recording sphygmomanometer is already known (DT-OS 22 26 652), in which the vibrations emitted by the bandpass filter remain unchanged are fed to the input of a threshold switch. As the positive and negative Half-waves of the oscillations of a Korotkow noise have irregular amplitude values the threshold voltage of the threshold switch is usually dimensioned in such a way that that the threshold switch is only set to those characteristic of the Korotkow noises responds to large amplitude values. Large amplitude values usually only have one Half-wave or two half-waves per Korotkow sound. Are two half waves larger Amplitude and different polarity, then the threshold switch reacts at least on a half-wave. On the other hand, there is only one half-wave of high amplitude and if this amplitude does not have the correct polarity, the threshold switch speaks not at all.

Advantages of the invention The method according to the invention with the characterizing Features of the main claim has the advantage that the evaluation of the Korotkow oscillations is considerably improved, so that by incorrect evaluation conditional measurement errors can be avoided. Another advantage is that the The resources required for this only mean a slight additional expense.

By By those listed in the subclaims Measurements are advantageous developments and improvements in the main claim specified procedure possible. It is particularly advantageous when in implementation of the method between the band-pass filter and the threshold switch, a full-wave rectifier circuit is provided.

Drawing An embodiment of the invention is shown in the drawing shown on the basis of two figures and explained in more detail in the following description. The drawing shows in FIG. 1 a block diagram of a device for measuring blood pressure and FIG. 2 is a detailed circuit diagram of that required to obtain the pulses Circuit part.

Description of the invention In the block diagram according to vlg. 1 referred to 1 an inflatable stasis cuff, which has a microphone 2; that is preferably a body-borne sound microphone, contains. a series connection connects to the structure-borne sound microphone from a preamplifier 3, one essentially only the frequencies of the Korotkow noises transmitting bandpass filter 4, a post-amplifier 5, a two-way rectifier circuit 6, a threshold switch 7 and a monostable trigger circuit 8.

from From an output line 9 of the monostable Toggle circuit 8 branch off three lines 10, 11 and 12, of which the first line 10 with a function display device 13, the second line 11 with a first Control device 14 and the third line 12 with a second control device 15 is connected.

A first output 16 of the first control device 14 is also available the function display device 13, a second output 17 with the second control device 15 and a third output 18 with a first electromagnet 19 of a two-digit manometer 10 in connection. Closes to a first output 21 of the second control device a second electromagnet 22, the two-pointer manometer 20 to. The two electromagnets each have an operative connection marked in FIG. 1 by dashed lines each with a pointer 23, 24 of the manometer in connection, and that can with the electromagnet 19 the first pointer 23 indicating the sytolic blood pressure and with the second Electromagnet 22 of the diastolic blood pressure indicating second pointer 24 des Pressure gauges are blocked or released.

Read at a second output 25 of the second control device @@@ seize a shutdown device 25, which is described in a manner below is used to automatically switch off the power supply of the blood pressure measuring device. The disconnection device has a first input 27 of an electronic memory 28 in connection, which also has a second input 39. One that can be operated by hand Switch 30 has a.

one, for example positive, terminal 31 of a battery 32 and with the other connection with the second input 29 of the memory 28 in connection. The battery 32 can be connected to a power supply device via the memory 28 33 are connected, the between a terminal 34 and a terminal 35 is a positive DC voltage and between the terminal 34 and a terminal 36 a negative Outputs DC voltage. The second input 29 of the memory 28 has an input 37 'he first control device 14 in connection. The entrance 37 is a Delay device 38 in parallel.

A pressure ball 39 intended for inflating the cuff 1 protrudes Air hoses 40 firstly with the cuff 1, secondly with the two-pointer manometer 2G and thirdly with a valve 41 in connection with the switch JJ mechanically is coupled.

The pressure ball 39 has a manually operated drain valve 42 for complete deflation of the cuff after a blood pressure measurement.

The operation of the device described above is as follows: If a patient wants to measure their blood pressure, they first place the tourniquet 1 at. Thereupon he switches the switch 30 to the position labeled p = "pumps" Switch division by. With the switchover, the valve 41 is closed. Simultaneously the then closed switch 30 leads to the positive potential of the battery 32 the second capture of the electronic memory 28, which is the switch state stores like a bistable multivibrator. This will automatically charge the battery 32 Battery 32 to the input of the power supply device 33 connected so that it emits the two stabilized DC voltages. With the switching on of the power supply are via the control devices 14 and 15 released the pointers of the two-pointer manometer 20, which were blocked in the initial state, by energizing the electromagnets 19 and 22.

When the power supply is switched on, the function display device is also activated 13 effective and a light source belonging to this device switched on. That If the light source lights up, this indicates that the cuff 1 is now with the pressure ball 39 can be inflated. The pointers 23, 24 of the manometer now show the with cuff pressure increases with inflation.

Has the patient inflated the cuff to a pressure value that is above his average systolic blood pressure, he switches the Switch 3G to the second switch position m = "Measure", whereby an automatic ongoing measuring process of systolic and diastolic blood pressure initiated The following happens in detail. The valve 41 is turned when you are strung of the switch 30 is opened so that the air contained in the cuff gradually can escape. The pressure reduction in the cuff occurs at one rate of, for example, 5 Torr / s for a certain duration of, for example, 1 s the delay device 38 to take effect. This device preferably includes an RC element whose capacitor is positive in the first switch position potential of battery 32 charged has loaded and when switching of the switch with the mentioned time delay via the associated resistor uploads.

With the last-mentioned lock it is intended that the patient after the switching of the switch 30 in the switch position m still has some time to to bring the limb carrying the cuff into a rest position before the automatic measurement begins, with the subsequent drop in cuff pressure a point is reached at which the previously congested blud begins to flow in the artery begins. At this time, pulsating kerotkov noises occur, emitted by the Microphone 2 arfanned and umgowendelt in electrical vibrations. With c) em preamplifier 3 amplified vibrations leaves the bandpass filter 4, which on e tuned for the Korotkon sound characteristic £ frequencies from 4G to 140 Hz is through, so that they can be further amplified in the post-amplifier 5.

The torotkow oscillations with positive and negative half-waves 43 (see. Fig. 1) are influenced by the full-wave rectifier circuit 6 so that d = ß all half-waves have the same pela @ity; see half waves 4 / s. Let through it evaluate the vibrations indicated by the threshold value switch 7 more reliably. the Threshold voltage Us the threshold switch 7 is dimensioned so that for the purpose of Disturbance water suppression only oscillations of relatively large amplitude the threshold switch sum up addressing them.

In the present example, the threshold value switch 7 is at a Korotkow noise produces two rectangular pulses 45, 46 through which the monostable Toggle circuit 8 is controlled. This toggle switch Toggle switch is in its quasi-stable state by the leading edge of the first pulse tilted, in which it remains until the expiry of, for example, 300 ms before it again tilts back to its stable state.

The toggle switch therefore gives a square-shaped sound for each Korotkow sound Pulse 47, which acts on the function display device 13 like a blocking pulse and briefly interrupts the lighting of the light source.

At the same time, the pulses 47 reach the first control device 14. A bistable multivibrator belonging to the first control device provides that only the leading edge of the first pulse 47 of the monostable multivibrator 8 the circuit for the electromagnet belonging to the first control device 19 interrupts, as a result of which the pointer 23 of the two-pointer manometer assigned to this electromagnet 20 is blocked. The pointer 23 remains at a pressure value that the systolic blood pressure.

The second control device 15 is designed so that they is influenced that the second electromagnet 22 with each pulse for the duration of the pulse (300 ms) is excited. This has the consequence that the assigned to him second pointer 24 to the instantaneous, between two successive Korotkow Korotkov noises sets a slightly decreased cuff pressure.

After each pulse 47, the pointer 24 becomes its own by being de-energized Electromagnet 22 blocked.

After the last pulse of the monostable multivibrator 8 resp.

after the last Korotkow sound, the second pointer of the manometer shows then the diastolic blood pressure.

About 1.5 to 2 s after the absence of another pulse from the monostable Toggle circuit 8, the disconnection device 26 sends a disconnection pulse to the memory 28, whereby the battery 32 is disconnected from the power supply device 33.

This ends the measuring process and the patient can use the drain valve Open 42 so that the air completely escapes from the cuff. Then he can Take off the cuff.

In Fig. 2, the structural units or components that are already shown in Fig. 1 occur, identified by the same reference numerals as in FIG. 1.

The microphone 2 is a structure-borne sound microphone with a piezoelectric Element 48 and a field effect transistor belonging to a microphone preamplifier 49, which is housed in the microphone housing. The preamplifier 3 contains as active amplifier element a first operational amplifier 50.

The band-pass filter tuned to the frequencies of the Korotkow noises 4 has a series connection of a low-pass filter with a second operational amplifier 51 and a high-pass filter with a third operational amplifier 52.

In In the lead to a non-inverting Input 53 of the second operational amplifier 51 is a series circuit of one first resistor 54 and a second resistor 55.

A line branches off between the two resistors 54, 55, the via a first capacitor 56 to the output 57 of the second operational amplifier 51 is connected. From the non-inverting input 53 of the second operational amplifier leads a connection via a second capacitor 58 to ground.

An inverting input 59 and the output 57 are galvanically connected to one another tied together.

Between the output 57 of the second and a non-inverting one Input 60 of the third operational amplifier 52 is a series circuit of one third capacitor 61 and a fourth capacitor 62 are provided. Between these A line branches off from both capacitors, through a third resistor 63 is connected to the output 64 of the third operational amplifier 52. Between the non-inverting input 60 and ground is a fourth resistor 65 A inverting input 66 is galvanic with output 64, which is simultaneously the The output of the bandpass filter 4 forms, so that the bandpass filter 4 is the Korotkow frequencies passes from s to 140 Hz; must have the resistance and resistance specified in FIG Capacity values are kept relatively precisely.

The post-amplifier 5 contains a fourth as a reinforcement element Operational Amplifier 67 Die The full-wave rectifier circuit 6 is designed as a so-called precision rectifier circuit, which is also used in small amplitude values of the Korotkow vibrations applied to it has a linear characteristic. The full-wave rectifier circuit 6 includes a fifth one Operational amplifier 68, a sixth operational amplifier 69, a first diode 70 and a second diode 71. Between the input of the full-wave rectifier circuit 6 and an inverting input of the fifth operational amplifier 68 is a Series connection of a capacitor 73 and a first resistor 74. Between the capacitor and the first resistor branches off a first line 75, which over a second and a third resistor 76, 77 to the output of the sixth operational amplifier 69 is connected. Between the first resistor and the inverting input of the fifth operational amplifier 68 branches off a second line 78, which over a series circuit of a fourth and a fifth resistor 79, 80 with a inverting input 81 of the sixth operational amplifier 69 is connected. While the first diode 70 a connection of the fourth resistor 79 to the output of the fifth operational amplifier 68 connects, the second diode 71 makes a connection between the second terminal of the fourth resistor 79 and the output of the fifth Operational amplifier 68. The two diodes 70, 71 are related to the output of the fifth operational amplifier polarized in opposite directions. The non-inverting inputs the operational amplifiers 68, 69 are at ground potential.

Of the The threshold switch 7 contains a seventh Operational amplifier 82, to which a voltage divider which determines the threshold voltage from two resistors 83, 84 belongs.

The monostable multivibrator 8 has an eighth as an active element Operational amplifier 85, the output of which is the output 86 of the monostable multivibrator 8 forms.

The eight operational amplifiers 50, 51, 52, 67, 68, 69, 82 and 85 are Components of integrated circuits, each integrated circuit being used for Example comprises four operational amplifiers.

The use of integrated circuits has the advantage of being small Power consumption and a small footprint. Both properties play a role a battery-operated, portable blood pressure monitor plays a crucial role.

Claims L e r s e i t e

Claims (6)

Claims 1. A method for measuring the blood pressure of a patient according to the Riva-Rocci / Korotkow method, in which the Korotkow noise is converted into electrical Vibrations are converted, the vibrations one to the frequencies of Korotkow sounds tuned band-pass filter and the vibrations transmitted by the band-pass filter a threshold switch are fed to each oscillation, the one exceeds a certain amplitude value, derives a signal that is a monostable Trigger circuit is supplied, the signals obtained from the Korotkow noise forms a pulse of a certain duration, the first received in the measurement Pulse a display element for displaying the systolic blood pressure and the last Impulse blocked a display element for displaying the diastolic blood pressure, thereby characterized in that the pass through the bandpass filter (4), positive and negative half-waves having vibrations (43) are influenced in such a way that all half waves run in the same direction before they hit the threshold switch (7) are supplied. 2. Device for performing the method according to claim 1, characterized characterized in that between the bandpass filter (4) and the threshold switch (7) a full-wave rectifier circuit (6) is provided. 3. Device according to claim 2, characterized in that the two-way rectifier circuit two operational amplifiers with one inverting and one non-inverting each Input and one output each, that in the feed line to the inverting input (72) of the first operational amplifier (68) is a series connection of a capacitor (73) and a first resistor (74) is that between the capacitor and the first resistor branches off a first line (75), which has a second and a third resistor (76, 77) connected to the output of the second operational amplifier is that between the first resistor (74) and the inverting input of the first operational amplifier (68) branches off a second line (78), which via a Series connection of a fourth and a fifth resistor (79, 80) with the inverting input (81) of the second operational amplifier is connected that one connection of the fourth resistor (79) via a first diode (70) and the other Connection via a second diode (71) polarized opposite to the first diode is connected to the output of the first operational amplifier and that the non-inverting Inputs of the operational amplifier are connected to ground. 4. Device according to claim 3, characterized in that the first, second, third and fourth resistors (74, 76, 77, 79) of the full-wave rectifier circuit (6) have a resistance value of about 200 kn, while the fifth resistance (80) has a resistance that is about half the resistance of the first, second, third or fourth resistor, and that the capacitor (73) has a capacitance value of about 0.1 F. 5. Device for performing the method according to claim 1, characterized characterized in that the bandpass filter (4) has two operational amplifiers in series (51, 52) with one non-inverting and one inverting input each as well each contains an output that is in the feed line to the non-inverting input of the first operational amplifier is a series circuit of a first and a second resistor (54, 55) is that between the two resistors a line branches off, which via a first capacitor (56) to the output (57) of the first Operational amplifier is connected to that the non-inverting input of the first Operational amplifier is connected to ground via a second capacitor (58), that inverting input (59) and output of the first operational amplifier galvanically are interconnected that between the output of the first and the non-inverting Input (60) of the second operational amplifier is a series connection of a third and fourth capacitor (61, 62) is that between the third and fourth Capacitor branches off a line which is connected to the via a third resistor (63) Output (54) of the second operational amplifier is connected to that of the non-inverting Input of the second operational amplifier via a fourth resistor (65) with Ground and the inverting input galvanically with the output of the bandpass filter forming output of the second operational amplifier is connected. 6. Device according to claim 5, characterized in that the first and the second resistor (54, 55) of the bandpass filter (4) each has a resistance value of about 10 k # that the first round capacitor (56) has a capacitance value of about 500 nF; the second capacitor (58) has a capacitance value of about 50 nF and the third and fourth capacitors (61, 62) each have a capacitance value of about 0.1 μf have that the third resistor (63) has a resistance of about 7 k # and the fourth resistor (65) has a resistance of about 60 k #. 1. Device for performing the method according to claim 1 characterized by a series connection of a microphone (2), a zoom amplifier (3), the Bandpass filter (4), a post-amplifier (5), the rectifier circuit (6), the Threshold switch (7) and the monostable toggle switch (8).