RU51851U1 - VERIFICATION DEVICE FOR AUTOMATED Sphygmomanometers - Google Patents

Abstract

The utility model relates to instrumentation and is intended for metrological certification of measuring blood pressure and heart rate and allows you to increase the accuracy of calibration of measuring blood pressure and heart rate while reducing its time by comparing systolic, diastolic pressure and heart rate of the calibrated sphygmomanometer with preset the values of these measured quantities. A device for the complete verification of automated sphygmomanometers contains a cylinder imitating a human hand with a compression cuff of a calibrated sphygmomanometer on it, a tube simulating an artery of a human hand, a working pressure standard, a pressure pulsation source, a pressure stabilization unit, a pressure control unit, the input of which is connected to the working output pressure standard, and the outputs with the inputs of the source of pressure pulsations, the working pressure standard. What is new is that a tube simulating the artery of a human hand is placed in the cavity of a cylinder simulating a human hand and is connected at one end to the first hydraulic output of the pressure pulsation source, and the other through the working pressure standard to the pressure regulator input, while the second hydraulic output the source of pressure pulsations is a bypass channel and is connected to the input of a pressure regulator electrically connected to a control unit, the electrical inputs of which are connected to a working pressure standard, and hydraulic In a personal way, with an input of a source of pressure pulsations, which contains a pump and a variable flow generator, which is a tapered cone-shaped cylinder, the first hydraulic output of which is the input of a tube simulating the artery of a human hand, and the second hydraulic output

is a bypass channel, and the generator input is hydraulically connected to the pump output, the hydraulic input of which is the output of the pressure regulator, while the electrical inputs of the pump and the variable flow generator are the outputs of the control unit, in addition, a pressure compensator is connected to the cylinder imitating a human hand.

Description

The utility model relates to instrumentation and is intended for metrological certification of measuring blood pressure and heart rate.

A known installation for checking automatic and semi-automatic blood pressure and heart rate meters of the company "OMRON CORPORATION" (Recommendation, State system for ensuring the uniformity of measurement. Automatic and semi-automatic blood pressure and heart rate meters OMRON and MARSHALL, MI 2582-2000, All-Russian Scientific research institute of optical and physical measurements (VNIIOFI) of the Gosstandart of Russia, M., 2000) - [1], which consists of a device for testing blood pressure meters, cuffs , cylinders for compression cuffs, simulator (setter) of pressure pulsations in the compression cuff, rigid chambers, air blower, electronic components, pneumatic systems with special metal and plastic fittings, tubes, plugs and adapters for connection to the device pneumatic system. The installation is characterized by the applicability of a limited number of types of devices, the presence of a methodological measurement error during verification associated with a forced departure from the simulation of the measurement process that actually occurs, and the impossibility of conducting a complete verification, in which the metrological characteristics of the measuring instrument are determined, which are inherent in it as a whole. In this case, only elementwise verification is possible, which is carried out when complete verification is not feasible (RMG 29-99, items 13.20 and 13.21, Recommendations on

interstate standardization, ICG. Metrology. Basic terms and definitions, IPK, Publishing house of standards, 2000) - [2].

A device is known "Variable flow generator" (USSR Author's Certificate No. 637722, G 01 F 25/00, Variable flow generator, publ. 15.12.78 Bull. No. 46) - [3] for determining the dynamic characteristics of flowmeters, containing a rotor in the form of a cylinder truncated by a plane at an angle of its longitudinal axis, a hollow cylindrical stator with a rectangular slot along the generatrix of the cylinder on the diametrically opposite side of the stator having a slot, the inner cavity of which is connected through an additional slot with an additional portion lump of the pipeline with the drain pipe, the generator is additionally equipped with a throttle device located in the drain pipe.

The invention is known “Installation for checking automated means of measuring blood pressure and heart rate” according to patent RU No. 2210974, A 61 5/02, published on 08.27.03 Bull. No. 24, - [4], which contains a cylinder simulating the patient’s hand for the compression cuff of the measuring instrument under test, a working pressure standard, a pressure pulsation generator simulating a pulse frequency and containing a quartz frequency generator and an electromagnet, the rod of which is made with an emphasis on the elastic bottom a cylinder for transmitting pressure pulsations through the oil to the cuff with a frequency set by the generator, a control unit, an air injection device and pneumatic system connection elements. Here, pressure pulsations are transmitted to the compression cuff through the entire cylinder simulating a hand, whereas in the real process pressure pulsations are transmitted only through the artery, and it is also necessary to disconnect the compression cuff from the calibrated measuring device to connect them through the connection element to the installation's pneumatic system, whereas types of measuring instruments

structurally not provided, and therefore, to verify such a tool on this installation is impossible.

Closest to the claimed utility model and coinciding with the intended purpose is the invention "Installation for the complete verification of blood pressure and heart rate" according to patent RU No. 2223031, A 61 V 5/02, published 02.10.04 Bull. No. 4 - [5 ]. The apparatus contains a source of pulsations of blood pressure in the form of a cylinder of elastic material, a compression cuff of the measuring instrument under test, a working pressure standard simulating a pulse rate, a control unit and a patient’s artery simulator in the form of an elastic tube rigidly connected to a cylinder and connected to an additional cylinder of elastic material . The compression cuff is worn on the tube and cylinder. The pressure pulsation regulator contains a quartz frequency generator and an electromagnet, the rod of which is in close contact with the bottom of the additional cylinder. The tube and cylinder are filled with liquid medium. The tube with its free end is connected to a chamber for damping pulsations (pressure stabilization unit) filled with a liquid medium.

The pressure pulsation regulator contains a quartz frequency generator and an electromagnet, the rod of which is in close contact with the elastic bottom of the additional hydraulic cylinder, which then passes into an elastic tube, which ends, in turn, with a pulsation damper. An electromagnet oscillates a rod, which, pushing the elastic bottom of the cylinder, transfers pulsations through the oil in the elastic tube to the compression cuff, thereby simulating a pulse frequency in the range of 0.5-4 Hz (30-240 beats per minute) with a resolution of 0.5 Hz and the limits of the relative error of 0.1%. The cylinder is connected to a working pressure standard, which is a pressure differential pressure transducer (differential pressure gauge) with a tolerance range of ± 0.075% in the range

Measurements from 4 to 40 kPa (30-300 mmHg) The positive chamber of the differential pressure gauge is connected by a tube of the pneumatic system to the cylinder, and the negative chamber is connected to the atmosphere. The installation is controlled by a control unit assembled on the basis of a personal computer. The source information used during verification is entered into the control unit, signals from the working pressure standard are also received here, which are then processed, and commands for the electromagnet of the crystal oscillator are issued from here. The tonometers are checked as follows:

- In the control unit enter the reference values of the measured values at the point being verified (P _b0 , P _n0 , f ₀ ).

- Air from the discharge device enters the cuff and through the tube to the differential pressure gauge, while the signal from the latter is constantly supplied to the control unit, and the pressure of the pumped-in air is displayed on the indicator.

- As soon as the pressure in the compression cuff exceeds the set value of P _n0 , the control unit will give a command to the quartz frequency generator, which starts the oscillation of the rod of the electromagnet with a frequency f ₀ . Pressure pulsations from the oscillations of the rod through the bottom of the cylinder, then the elastic tube is transmitted to the cuff and through it to the calibrated tonometer.

- As soon as the pressure in the hydraulic system rises to the value of P _в0 , the control unit gives a command to the quartz frequency generator, which stops the oscillation of the rod of the electromagnet with a frequency f ₀ .

- According to the programs included in the automated blood pressure monitors, after the pressure in the cuff of the systolic value P _{b0 is} exceeded, the discharge device is not turned off and the pressure in the cuff continues to increase for some time. In the case of semi-automated blood pressure monitors, air injection in this way is carried out in manual mode.

- Then, the exhaust valve is opened on the tonometer being verified, and the pressure in the cuff starts to decrease, while it is continuously measured using a differential pressure gauge, from which the measuring signal is transmitted to the control unit.

- As soon as the pressure in the cuff drops to the value of Р _в0 , the control unit will give a command to the quartz frequency generator, which starts the oscillation of the rod of the electromagnet with a frequency f ₀ .

- The air continues to bleed further, and as soon as the pressure in the hydraulic system reaches the value of P _n0 , the control unit gives a command to stop the oscillations of the rod of the electromagnet. The display digits appear verified tonometer (P _a, P _n f), are compared with reference values of measured values at a given point (P _B0, P _H0, f _0). Similarly, the tonometer is checked at several more points, after which a decision is made on its suitability or unsuitability for further use.

The invention was solved with the achievement of a technical result — a decrease in the methodological component of the measurement error, but here there is a departure from simulating the real process of measuring blood pressure and heart rate, because the tube imitating the artery of the hand is in close contact with the cylinder, on which the compression cuff is worn, which does not provide the necessary accuracy of verification.

The technical result, which is achieved by the claimed utility model, is to increase the accuracy of calibration of measuring blood pressure and heart rate.

The technical result is achieved by the fact that in the calibration device of automated sphygmomanometers containing a cylinder imitating a human hand with a compression cuff of a verified sphygmomanometer on it, a tube simulating an artery of a human hand, a working pressure standard, a source of pressure pulsations, a unit

pressure stabilization, the control unit, the input of which is connected to the output of the working pressure standard, and the outputs are the inputs of the pressure pulsation source, working pressure standard, it is new that the tube simulating the artery of a person’s hand is placed in the cavity of a cylinder imitating a person’s hand, and connected at one end to the first hydraulic output of the pressure pulsation source, and the other through a working pressure standard with the pressure regulator input, while the second hydraulic output of the pressure pulsation source is bypass channel and is connected to the input of the pressure regulator, electrically connected to the control unit, the electrical inputs of which are connected to the working pressure standard, and hydraulically - to the input of the pressure pulsation source, which contains a pump and a variable flow generator, which is a tapered cone-shaped cylinder, the first hydraulic output which is the input of a tube simulating the artery of a human hand, and the second is a bypass channel, and the input of the generator is hydraulically connected to the output of the pump, hydra the influential input of which is the output of the pressure regulator, while the electrical inputs of the pump and the alternating flow generator are the outputs of the control unit, in addition, a pressure compensator is connected to the cylinder imitating a human hand.

The essence of the utility model is illustrated in the drawing, where:

1 - source of pressure pulsations;

2 - variable flow generator;

3 - pump;

4 - working pressure standard;

5 - cylinder imitating a human hand;

6 - a tube simulating a human artery;

7 - measuring channel;

8 - bypass channel;

9 - control unit;

10 - pressure compensator;

11 - pressure regulator;

12 - compression cuff;

13 - sphygmomanometer.

The calibration device of automated blood pressure and heart rate measuring devices contains a pressure pulsation source 1, which contains a pump 3 and a variable flow generator 2, one input of which is hydraulically connected to the pump 3, and the second input is electrically connected to the control unit 9, which is a personal computer . At the output of the variable flow generator 2, there are two rigid tubes forming the measuring channel 7 and the bypass channel 8. The measuring channel 7 is the first hydraulic output of the variable flow generator 2, contains a sensor zone in the form of a flexible elastic tube 6 simulating the artery of a human hand and located in the cavity of a cylinder 5 simulating a human hand, and a working pressure standard 4 transmitting a signal to the control unit 9. A compression sleeve 12 of the verified sphygmomanometer 13 is put on the cylinder 5 and a pressure compensator 10 is connected. The device includes a pressure regulator 11 hydraulically connected to the pump 3, a control unit 9, an outlet s which is electrically connected to pump 3, a pressure regulator 11, an alternating flow generator 2, and the input control unit 9 outputs the operating pressure is 4 standard.

The pump 3 and the variable flow generator 2 connected in series form a source of pressure pulsations 1, the input of which is electrically connected to the control unit 9. The hydraulic outputs of the generator 2 comprise measuring 7 and bypass 8 channels connected to the input of the pressure regulator 11, the electrical input of which is connected to the control unit 9. The measuring channel is a rigid tube with a dedicated sensor area in the form of flexible elastic

a tube 6 simulating the artery of a human hand located in the cavity of a cylinder 5 simulating a human hand, on which a compression cuff 12 of a verified sphygmomanometer 13 is put on, in addition, the cylinder 5 is connected to a pressure compensator 10. A working pressure standard 4 is connected to the control unit 9, representing a digital complex for measuring pressure, transmitting a signal from a measuring channel 7.

The device operates as follows.

The control unit 9 sets the reference pressure values, the signal from which enters the pump 3, and the frequencies, the signal from which it enters the variable flow generator 2. The flow of incompressible liquid from the pump 3 through the constant cross-section pipe enters the variable flow generator 2, which is beveled cone-shaped cylinder, which, rotating with a frequency set from the control unit 9 equal to the heart rate, passes it through two rigid tubes, forming measuring 7 and bypass 8 channels, through which the passage so fluid flows, characterized antiphase sinusoidal. Sinusoidal pressure pulsations from the variable flow generator 2 are perceived by a flexible elastic tube 6 simulating the artery of the human hand and located inside the cavity of the cylinder 5, which, through the technical oil in the cylinder 5 simulating the human hand, are perceived by the compression cuff of the calibrated sphygmomanometer. A pressure compensator 10 is connected to the cylinder 5 for stable maintenance of the pressure in the cylinder 5. In addition to the sphygmomanometer being calibrated, the measured pressure and frequency are sensed by the working pressure standard 4 (Pressure measuring complex digital SPDC model 89018-01, Technical description and instruction manual, 3.9026.288- 01 TO) - [6], which is a digital complex for measuring pressure with a margin of 0.06%, which processes the incoming measurement information and provides

control pulses to the control unit 9. A stable pressure in the entire system is supported by a pressure regulator 11, which receives signals from the control unit 9.

Measurement of systolic, diastolic pressure and heart rate is carried out by a sphygmomanometer on cylinder 5, imitating a human hand. The obtained values of the sphygmomanometer are compared with systolic, diastolic pressure and heart rate set from the control unit 9, the signals to which come from the working pressure standard 4. Similarly, the measuring instrument is checked at several more points and a decision is made on its suitability or unsuitability for use.

Thus, the problem to be solved is achieved, on the one hand, by creating periodic (sinusoidal) pressure pulsations with a variable flow generator, and on the other hand, a tube simulating the artery of a human hand is located in the cavity of a cylinder imitating a human hand, as it happens in reality. In the prototype, both of these signs are absent.

A device is proposed in which calibration of automated measuring instruments for blood pressure and heart rate is carried out in full, while the solution to this device is simple in execution, simple and reliable in operation.

Claims (4)

1. The calibration device of automated sphygmomanometers, containing a cylinder simulating a human hand, with a compression cuff of a calibrated sphygmomanometer on it, a tube simulating the artery of a human hand, a working pressure standard, a source of pressure pulsations, a pressure stabilization unit, a control unit whose inputs are connected to the outputs working pressure standard, and the output with the input of the source of pressure pulsations, characterized in that the tube simulating the artery of a person’s hand is placed in the cavity of the cylinder, simulating the human hand, and is connected at one end to the first hydraulic output of the pressure pulsation source, and the other through the working pressure standard to the pressure regulator input, while the second hydraulic output of the pressure pulsation source is a bypass channel and connected to the input of the pressure regulator electrically connected to the control unit whose electrical inputs are connected to a working pressure standard, and hydraulically - to the input of a pressure pulsation source. 2. The verification device according to claim 1, characterized in that the source of pressure pulsations comprises a pump and a variable flow generator, the first hydraulic output of which is the input of a tube simulating the artery of the human hand, and the second hydraulic output is a bypass channel, and the generator input is hydraulically connected to the output of the pump, the hydraulic input of which is the output of the pressure regulator, while the electrical inputs of the pump and the variable flow generator are the outputs of the control unit. 3. The verification device according to claim 1, characterized in that the variable-flow generator is a beveled conical cylinder. 4. The verification device according to claim 1, characterized in that it comprises a pressure compensator connected to a cylinder imitating a human hand.