SU728833A1 - Apparatus for measuring blood-flow time-interval - Google Patents

Description

The invention relates to the field of medical technology, in particular to devices for measuring blood flow time in the diagnosis of cardiovascular diseases and the monitoring of tolerance to physical activity.

A device for measuring blood flow time, comprising an oxidizer and a respiration sensor, the outputs of which are connected to the inputs of a two-channel amplifier, and a recording device (1).

However, the known device has a low accuracy in measuring blood flow time.

The aim of the invention is to improve the accuracy of measuring blood flow.

This is achieved by the fact that a minimum signal determination circuit, a time counter control circuit, and a time counter are connected to the device, the output of which is connected to a recording device and to one of the inputs of the time counter control circuit, the second input of which is connected to the first output of the two (Nalny amplifier, second the output of which is connected via the O CG determination circuit, with

The time counter control circuit contains the Former, two triggers and two And circuits, the input of the former is connected to the first output of the two-channel amplifier, and the output to the first inputs of two And circuits, the single input of the first trigger is connected to the output of the time counter, the direct output of the first trigger connected to the second input of the first circuit And, the output of which is connected to the single! -_ input of the second trigger: inverse, the 15th output of which is connected to the second input of the second circuit And, the output of which is connected to the input of the time counter,

The drawing shows a structural diagram; devices for measuring blood flow

A device for measuring blood flow time contains an oxidizer 1 and a respiration sensor 2, connected by their 25 outputs to a two-channel amplifier 3. One of the outputs of amplifier 3 is connected to the reset input of the time counter 4 through the time counter control circuit 5. Another 30 amp output. 3 is connected to the circuit 6 for determining the minimum signal at the output of the oxidizer, the output of which is connected to the control input of the recording device 7, the information inputs of which are connected to the outputs of the time counter 4.

The time counter control circuit 5 contains a clock generator 8, two triggers 9 and 10, and two circuits 11 and 12 I. Moreover, the input of the clock generator 8 is connected to the output of amplifier 3, and the output to the inputs of circuits 11 and 12. A single input of trigger 9 is connected with the output of the time counter 4, and the direct output of the trigger 9 is connected through the circuit 11 And to a single input of the trigger 10, the inverse output of which through the circuit 12 And is connected to the input of the counter 4 time. >

The device operates as follows.

The oxidizer 1 is strengthened on the earlobe of the subject, the respiratory sensor 2 is on the chest.

A pulse is applied to the dump bus and the triggers 9 and 10 are set to zero. The signal from the respiration sensor 2 is supplied through an amplifier 3 to the sync pulse generator 8, which generates two sync pulses for each inspiratory-expiration cycle. These clock pulses pass through an open circuit 12 And to the reset input of the time counter 4, setting it each time to zero. Through circuit 11 And the clock pulses do not pass, since a logical “0” comes from the trigger 9 to the second input. When holding the breath, clock pulses are not formed, and the time counter starts calculating the clock pulses. After a time interval shorter than the minimum breath holding time (10 s), the time counter generates an impulse that sets trigger 9 to a single state, i.e. the control circuit pauses.

With the resumption of breathing ', the shaper of 8 clock pulses begins to work. The first clock pulse resets the time counter 4 to the zero state and, having passed through the circuit 11. And, it flips the trigger 10 to the single state. Scheme 12 And it closes and subsequent clock pulses do not arrive at the reset input of the time counter, which again begins to count clock pulses. At the time of the appearance of the minimum oxy signal, the circuit 6 for determining the minimum signal at the output of the oxidizer generates a pulse that enters the control input of the recording device 7, fixing in it a code from the time counter corresponding to the time interval from the moment of resuming breathing to the minimum value of the oxy signal, t, e , blood flow time at the lung-ear site.

The application of the proposed device allows to increase the accuracy of measuring blood flow time in the lung-ear section, which allows the doctor to analyze the hemodynamic changes (both in the small circle and in the greater circulation) against the background of the ultimate intensification of functioning structures (pronounced compensation), as well as in cases when additional functional loads lead to minor changes in blood flow time.

Claims (2)

one The invention relates to the field of medical technology, namely, devices for measuring the time of blood flow in the diagnosis of cardiovascular diseases and monitoring exercise tolerance. A device for measuring the time of blood flow is known, which contains an oxidizer and a respiration sensor, the outputs of which are connected to the inputs of a two-channel amplifier, and a recording instrument {1}. However, the known device has a low accuracy of measuring the time of blood flow. The aim of the invention is to improve the accuracy of measuring the flow time 1. This is achieved by introducing a minimum signal detecting circuit, a time counter control circuit, and a time counter whose output is connected to a recording device and to one re input of the time counter control circuit, the second input of which is connected to the first output of the two amplifier, the second the output of which is connected through the circuit of determining the angular-hour;. -.Argh / e; register with: p gzgg Scheme. Iri-iri account-ii-com contains a forg-grsvatel, two triggers and two circuits AND, the input of the imager is connected to the first output of the two-channel amplifier, and the output to the first goes back, r1 two schemes AND To the output of the time counter, the direct output of the first trigger is connected to the second input of the first circuit Hf, the output of which is connected to the single input of the second trigger ,; inverse The 5th output of which is connected to the second input of the second cxeNM I, the output of which is connected to the input of a time counter. The drawing shows a structure on the circuit | device for measuring blood flow The device for measuring the blood flow time contains oxidizer 1 and respiration sensor 2, connected by their 5 outputs to a dual channel amplifier 3. One of the outputs of amplifier 3 is connected to the reset input of counter 4 times via a time counter control circuit 5. Another output amplifier, 3 is connected to circuit 6 by determining the minimum signal at the oxidizer output, the output of which is connected to the control input of the recording device 7, the information inputs of which are connected to the outputs of the time counter 4. The time counter control circuit 5 contains a driver of 8 clock pulses, two triggers 9 and 10, and two circuits 11 and 12 I. Moreover, the input of the clock generator of 8 clock pulses is connected to the output of amplifier 3, and the output to the inputs of circuits 11 and 12 I. A single trigger input of 9 st with the output of the counter 4 times, and the direct output of the trigger 9 is connected via the circuit 11 And to the unit 1 "1 input of the trigger 10, the inverse output of which 12 and 12 is connected to the input of the counter 4 time. The device works as follows. Oxidator 1 is fastened on the patient's earlobe, and respiration sensor 2 is mounted on the chest. A pulse is applied to the waste bus and triggers 9 and 10 are set to the zero state. The signal from the sensor 2 breath comes through, the amplifier 3 to the shaper 8 clock pulses, - which produces inhale-exhale two sync pulses for each cycle. These sync pulses go through the open circuit 12 And to the waste input of the counter 4 times, setting it to the zero state each time. Through circuit 11, the clock pulses do not pass, since the logical input O comes from the trigger 9 to the second input. When the breath is held, the clock pulses do not form and the time counter begins to calculate clock pulses. After a time interval shorter than the minimum breath-holding time (10 s), the time counter outputs a pulse that sets trigger 9 to one state, i.e. control circuit captures a pause. When breathing resumes, the shaper 8 of the synchroimpus begins to work; The first clock pulse resets the counter 4 times to the zero state and, after passing through the circuit 11. AND, flips the trigger 10 to the single state. Circuit 12 also closes and subsequent clock pulses do not arrive at the reset input of the time counter, which again begins to count clock pulses. At the time of the occurrence of the minimum oxysignal, the minimum signal at the output of the oxidizer output circuit 6 generates a pulse that arrives at the control input of the recording device 7, fixing in it a code from the time counter corresponding to the time interval from the moment of breathing to the minimum value of oxysignal, t, e, the time of blood flow in the area of the lungs-ear. The use of the proposed device improves the accuracy of J. from the point of time of blood flow, and the lung-ear section, which allows the doctor to analyze hemodynamic changes (both in the lesser circle and the greater circulation) against the background of the extreme intensification of functioning structures (pronounced compensation), as well as in cases where additional functional loads result in insignificant changes in 5 times the blood flow. Invention Formula  A device for measuring the time of blood flow, containing an oxidation sensor and a breathing sensor, the outputs of which are connected to the inputs of a two-channel amplifier, and recording device different In that, with a circuit for improving the accuracy of measuring the blood flow time, a minimum signal detection circuit, a time counter control circuit and a time counter, the output of which is connected to the recording device and one of the time counter control inputs, are entered into the device; the second input is connected to the first output a two-channel amplifier, the second output of which is connected through a circuit for determining the minimum signal to a recording device. 2. The device according to claim 1, characterized in that the time meter control circuit comprises a driver, two triggers and two Ands, the input of the imager is connected to the first output of the channel amplifier, and the output to the first input of two And schemes, the single input of the first trigger is connected to the output of the time counter, the direct output of the first trigger And connected, the output of which is connected to unit input of the second trigger, the inverse output of which is connected to the second input of the second circuit And the output of which is connected to the input of the time counter. Sources of information taken into account in the examination 1, Sviridov A.M. A pneumoacilography unit for testing the functional state of the blood circulation and the sledge. Medical Technology, 4, 1973, p. 50 (prototype).