RU2725856C1 - Apparatus for verification of non-invasive sphygmomanometers - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention refers to medical equipment, namely to apparatus for calibrating non-invasive sphygmomanometers. Apparatus for verifying non-invasive sphygmomanometers (14) comprises cylindrical vessel (3) with a fluid for attaching compression cuff (2) of the tested sphygmomanometer, a pressure pulsation device, a pressure sensor and its pulsations (5). Pressure pulsation setter serves to transfer pressure pulsations with preset frequency to compression collar and is connected to comparator and control unit. Outputs of the pressure sensor and its pulsations are connected to the comparator and control unit (9) and to the input of the measurement unit and smoothing the pressure pulsations. Cylindrical vessel is connected by one end face with deformable nozzle (1), and by another one – with pressure generating element and its pulsations (4). Pressure vessel and its pulsations are placed in the cylindrical vessel. Output of the measurement unit and smoothing pressure pulsations (11) is connected to the first input of comparator (12). Output of the comparison device is connected to the input of the pressure difference logger and its pulsations (13) and to the input of the comparison and control unit. Second input of comparator is connected to output of sensor and meter of external static pressure (10). Pressure pulsation setter is made in the form of series-connected pressure generator and its pulsations (8) and drive (7). Actuator stem (6) is made in contact with the pressure generating element and its pulsations and allows simultaneous generation of the reference pressure values and their pulsations in the inner cavity of the cylindrical vessel.EFFECT: enlarging possibility of verification of sphygmomanometers of various types with provision of specified accuracy of pressure measurements and frequency of pulsations.3 cl, 1 dwg

Description

The invention relates to measuring equipment and is intended for verification of non-invasive sphygmomanometers (blood pressure and heart rate meters).

A known installation for checking channels for measuring pressure and pulse rate is UPKD-2 (State Register No. 44539-10, certificate of registration type SI No. 40026), in which a pressure pulsation simulator generates air pressure pulses that occur when working with a real patient. The microcontroller, in accordance with the specified parameters, forms the envelope of the pulse signals, which allows you to simulate the values of systolic and diastolic pressures. After connecting the device and the cuff to the unit, the channel for measuring the pulse rate and the rate of pressure decrease is sequentially checked, then the calibrated tonometer is put into service mode, the channel for measuring the pressure is checked, and then its pneumatic system is sealed.

The disadvantages of the installation include:

1) lack of compensation of the set pressure parameters and its pulsations from external influencing factors (for example, temperature, atmospheric pressure, etc.);

2) the lack of simultaneous and interconnected control channels for measuring pressure and heart rate.

The invention is known "Method and device for tonometer calibration using a patient simulator" according to patent RU No. 2323210, АВВ 5/022, G09B 23/28, published on 07.20.08 Bull. No. 19, containing a patient simulator made in the form of a patient’s organ, used to measure blood pressure and pulse, a tube with a liquid connected to the volume and a receiver with a liquid, a sensor for static pressure of the liquid and a sensor for fluctuations in the pressure of the liquid in the volume with the liquid, as well as contact with a volume of liquid, the fixed part of the body of the volume with liquid and the movable part of the body of the volume with liquid, while the movable part of the body is connected to a lever having a pivot axis with a direction of rotation, driven by an eccentric drive with a speed controller having a direction of rotation of the eccentric and direction moving the rotation axis, in addition, contains a sphygmomanometer with an inflated cuff and a processing unit for the measurement results.

The disadvantages of the invention include the following:

1) the great complexity of the calibration, because you must first determine the calibration coefficient of the patient simulator using a pre-calibrated tonometer, introducing the latter into the calibration results, and then calculate the calibration coefficient of the calibrated tonometer;

2) during verification (calibration) do not take into account the influence of external factors (e.g. temperature, atmospheric pressure, etc.) on the readings of the static pressure sensor and the vibration sensor when measuring the pressure in the device.

3) the high complexity of creating a controlled pressure in the volume with a liquid eccentric electric drive;

4) use of a compression cuff of only one given size.

Closest to the claimed invention is the invention "Installation for checking automated means of measuring blood pressure and heart rate" according to patent RU No. 2210974, АВВ 5/02, published on 08.27.2003 Bull. No. 24, comprising a simulator of a patient’s blood pressure pulsations in the form of a cylinder made of elastic material, a compression cuff of a calibrated measuring instrument, a working pressure standard, a pressure pulsation adjuster, an air injection device connected to a compression cuff of a calibrated means through a pneumatic system connection element, a control unit, the first input and the output of which is connected respectively to the output and input of the working pressure standard, and the second input and output of the control unit are connected to the output and input of the pressure pulsation adjuster, configured to set the heart rate on the cylinder, while the air injection device is connected to the working through the pneumatic system connection element pressure standard, and the cylinder is made of elastic material and is filled with a liquid medium. The pressure pulsation regulator comprises a quartz frequency generator and an electromagnet, the rod of which is made with emphasis in the cylinder for transmitting pressure pulsations to the compression cuff with a frequency specified by the quartz generator.

The disadvantages of the invention include:

- the need to disconnect the compression cuff from the calibrated measuring device for connecting them through the connection element to the installation pneumatic system, while for some types of measuring instruments the cuff is not structurally disconnected, and therefore, it is impossible to verify such a device on this installation;

- application only for verification of sphygmomanometers with shoulder cuffs;

- lack of compensation of the set pressure parameters and its pulsations in the simulator of pulsations of blood pressure from external influencing factors (for example, temperature, atmospheric pressure, etc.);

- there are no mechanisms for accurately maintaining pressure in the cylinder with the liquid.

The problem is low efficiency: exposure to external factors; limited range of types of verified instruments; the complexity of creating controlled pressure and its pulsations in the volume with the liquid with a given accuracy.

The technical result, to which the claimed invention is directed, is to expand the ability to verify various types of sphygmomanometers with a given accuracy of pressure measurements and pulsation frequency.

The technical result is achieved by the fact that in the installation for checking non-invasive sphygmomanometers, containing a cylindrical vessel with liquid for attaching the compression cuff of the sphygmomanometer to be verified, a pressure pulsation regulator serving to transmit pressure pulsations to the compression cuff with a given frequency and connected to the control unit, the pressure sensor and its of pulsations, the output of which is connected to the control unit, it is new that a cylindrical vessel is connected by one end end to a deformable nozzle, and the other by an element for creating pressure and its pulsations, inside which a pressure and pulsation sensor is placed, the output of which is connected to the input of the unit measuring and smoothing pressure pulsations, the output of which is connected to the input of the comparison device, the first output of which is connected to the input of the differential pressure recorder and its pulsations, and the second to the input of the comparison and control unit, and the input to the output of the sensor and external static pressure meter I, besides this, a pulsation pressure regulator is introduced into it, made in the form of a series-connected pressure generator and its pulsations and a drive, the output of which is connected to the element for creating pressure and its pulsations by an adjustable rod. The pressure pulsation adjuster is configured to simultaneously generate a reference value of pressure and its pulsation in the inner cavity of the cylindrical vessel. The housing is made with the possibility of mounting compression cuffs with various deformable nozzles for the respective sizes of the calibrated sphygmomanometers. The element of creating pressure and its pulsations in the volume with the liquid is made in the form of a bellows. The adjustable stem is based on a screw joint.

The invention is illustrated in FIG. 1, which shows the structural-functional diagram of the installation for checking non-invasive sphygmomanometers:

1 - deformable nozzle;

2 - compression cuff;

3 - cylindrical body;

4 - an element of creating pressure and its pulsations;

5 - pressure sensor and its pulsations;

6 - stock;

7 - drive;

8 - pressure generator and its pulsations;

9 - block comparison and control;

10 - sensor and meter of external static pressure;

11 - unit for measuring and smoothing pressure pulsations;

12 is a comparison device;

13 - recorder differential pressure and its pulsations;

14 - non-invasive sphygmomanometer.

The installation for checking non-invasive sphygmomanometers consists of a cylindrical vessel with a liquid, made in the form of a cylindrical body 3, rigidly connected to a deformable nozzle 1, on which a compression cuff 2 of the verified sphygmomanometer 14 is put on. To create the nominal pressure and its pulsations from one end of the body 3 is installed an element for creating pressure and its pulsations 4, which is affected by the rod 6 of the actuator 7, connected to the comparison and control unit 9 through a pressure generator and its pulsations 8. A pressure sensor and its pulsations 5 is installed in the inner cavity of the cylinder, which processes the incoming measurement information and transmits signals to the comparison and control unit 9. Simultaneously, through the unit for measuring and smoothing pressure pulsations 11, the signal from the pressure sensor and its pulsations 5 receives a signal to the comparison device 12, which generates the difference of pressure parameters from the pressure sensor and its pulsations 5 and the sensor and external static meter pressure 10 and passes to the registrar differential pressure and its pulsations 13.

Simulation of the heart rate at the installation is carried out by a controlled drive in the range of 0.5-4 Hz (30-240 beats per minute), which, on command from the comparison and control unit 9, sets the oscillation frequency of the stem 6. The stem 6 acts on the element located in the housing 3 creating pressure and its pulsations 4, made, for example, in the form of a bellows, and creating a variable force F proportional to the magnitude of the generated pressure and its pulsations in a cylindrical vessel. In this case, the rod 6 simultaneously creates a predetermined reference pressure and its pulsations in the inner cavity of the cylindrical vessel, which are perceived by the cuff 2. To control the pulsation frequency f ₀ , a pressure generator and its pulsations 8 are used, which is made, for example, based on a crystal oscillator. Thus, an imitation and control of the resonant pulsation of pressure in a cylindrical vessel occurs when measuring pressure.

The cylindrical body 3 is configured to mount compression cuffs 2 with various deformable nozzles 1 for the respective sizes of the calibrated sphygmomanometers, thereby the installation can be oriented to sphygmomanometers with different sizes of compression cuffs. The generated pressures and their pulsations inside the housing 3 are sensed by the pressure sensor and its pulsations 5, the average values of which through the unit for measuring and smoothing the pressure pulsations 11 are compared with the readings of the sensor and external static pressure meter 10. In this case, the comparison device 12, which determines this pressure drop, generates a signal to the differential pressure recorder and its pulsations 13 and the comparison and control unit 9, with which the readings of the calibrated sphygmomanometer 14 are compared.

The operation of the installation for checking non-invasive sphygmomanometers in FIG. 1 is carried out as follows.

Using rod 6, the values of the readings of the differential pressure recorder 13 and its pulsations are reduced to zero compared to the reference signal from the external static pressure sensor 10, thereby compensating for the effect of atmospheric pressure on the calibration results.

Then, the comparison and control unit 9 creates a nominal value of _Pnom and its pulsation with a set frequency f ₀ due to the impact of the rod 6 on the pressure generating element and its pulsations 4 in the cylindrical vessel. When this rod 6 makes a reciprocating motion and its control is carried out by the actuator 7 as the degree of effort on the pressure element 4, and the frequency of exposure. These effects are converted by a pressure sensor and its pulsations 5 into a change in its parameters in proportion to their values. The value of the ripple parameter is supplied to the first input of the comparison and control unit 9, where this regulation channel is brought to a predetermined value.

The nominal pressure P _nom through the unit 11 for measuring and smoothing pressure pulsations and the comparison device 12 is supplied to the second input of the unit for comparison and control 9, where this control channel is brought to a predetermined value. The pulsation frequency ƒ ₀ in the volume with the liquid is controlled by a pressure generator and its pulsations 7. The differential pressure and its pulsations recorder 13 fixes the average pressure value P _nom set by the comparison and control unit 9, the liquid pressure drop by the static pressure sensor 10 and pressure pulsation sensor 5, as well as ripple parameter values.

The compression cuff 2 of the verifiable sphygmomanometer 14 is fixed to the deformable nozzle 1. Then, the verifiable sphygmomanometer 14 is turned on, which acts on the nozzle 1 by the programmed cuff 2 according to the programmed algorithm of its operation, increasing the pressure in the housing 3 above a predetermined control system, and then starts to bleed it, while the differential pressure and its pulsation recorder 13 captures the process of forcing and bleeding pressure in the deformable nozzle 1. These changes are also recorded by the pressure sensor and its pulsations 5 and transmitted to the comparison and control unit 9.

In the process of bleeding pressure sensor 5 and its pulsations, the value of the upper pressure P _max and its pulsation is determined. When the set pressure comparison and control unit 9 reaches the upper pressure and its pulsations, the differential pressure recorder and its pulsations 13 writes to the memory the obtained value of the upper pressure P _max and its pulsations.

In the process of further bleeding in the cuff 2, the value of the lower pressure P _min and its pulsation is similarly determined, and the differential pressure recorder and its pulsations 13 records the corresponding value of the lower pressure P _min and its pulsation.

The obtained readings of the non-invasive sphygmomanometer 14 (upper P _max and lower P _min pressure, pulsation frequency ƒ ₀ ) are compared with the readings of the differential pressure recorder and its pulsations 13. Identify the pressure and the frequency of its pulsations at other points regulated by the calibration method by setting these values in the comparison and control unit 9.

The technical result is achieved by orienting calibration sphygmomanometers with different sizes of compression cuffs without violating their integrity, as well as accurately maintaining the pressure in the cylindrical vessel with compensation for errors in the set pressure parameters and their pulsations caused by external influencing factors, which is not achieved in the prototype. The claimed technical solution allows you to expand the range of types of devices to be verified with a given accuracy of pressure measurements and the frequency of pulsations.

Thus, a device is proposed in which the calibration of automated sphygmomanometers is simultaneously and interconnected, both by pressure channels and by the pulsation frequency, while the solution to this device is simple in execution, simple and reliable in operation.

Claims (3)

1. Installation for verification of non-invasive sphygmomanometers, containing a cylindrical vessel with liquid for attaching a compression cuff of the calibrated sphygmomanometer, a pressure pulsation regulator, used to transmit pressure pulsations with a given frequency to the compression cuff and connected to the comparison and control unit, a pressure sensor and its pulsations, output which is connected with the comparison and control unit, characterized in that in the cylindrical vessel connected by one end end to the deformable nozzle and the other by the pressure generating element and its pulsations, a pressure and its pulsation sensor is placed, the output of which is connected to the input of the measuring unit and smoothing the pressure pulsations, the output of which is connected to the first input of the comparison device, the output of which is connected to the input of the differential pressure recorder and its pulsations and to the input of the comparison and control unit, and the second input - to the output of the sensor and external static pressure meter, in addition, to it introduced for a pressure pulsation sensor made in the form of a series-connected pressure generator and its pulsations and a drive, the rod of which is made in contact with the element for creating pressure and its pulsations, and which allows to simultaneously generate reference values of pressure and their pulsations in the internal cavity of a cylindrical vessel. 2. Installation for checking non-invasive sphygmomanometers according to claim 1, characterized in that the housing is configured to mount compression cuffs with various deformable nozzles for the respective sizes of the verified sphygmomanometers. 3. Installation for checking non-invasive sphygmomanometers according to claim 1, characterized in that the element for creating pressure and its pulsations in the volume with the liquid is made in the form of a bellows.

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