RU105572U1 - HUMAN HAND SIMULATION MODEL FOR VERIFICATION OF MEANS OF MEASUREMENT OF ARTERIAL PRESSURE AND FREQUENCY OF HEART REDUCTIONS - Google Patents

Abstract

 1. A simulation model of a human hand for checking blood pressure and heart rate measuring instruments, comprising a first cylinder that simulates the upper third of the shoulder, for attaching a compression cuff of the sphygmomanometer to the shoulder, in which an elastic tube with a locking-regulating element imitating the artery of the upper third is placed shoulder, a second cylinder that simulates the lower third of the shoulder, for attaching a compression cuff of the sphygmomanometer to the wrist, in which an elastic tube with a lock is placed o-regulating element that simulates the artery of the lower third of the shoulder, a locking regulating element connecting, hydraulically combining the first and second cylinders, characterized in that the elastic tube of the second cylinder is made in the form of three parallel elastic tubes with locking and regulating elements, and the elastic tube of the first cylinder contains an additional locking and regulating element. ! 2. A simulation model of a person’s hand for checking blood pressure and heart rate measuring instruments according to claim 1, characterized in that the elastic tubes of the second cylinder are made of different diameters. ! 3. A simulation model of a human hand for checking blood pressure and heart rate measuring instruments according to claim 1, characterized in that a shut-off and control element is installed in the bypass tube of the second cylinder.

Description

The utility model relates to the field of instrumentation, in particular to instrumentation and is used as part of a calibration installation for metrological certification of blood pressure and heart rate meters.

A known installation for checking automated measuring instruments for blood pressure and heart rate (Patent RU No. 2210974, АВВ 5/02, publ. 08/27/03, Bull. No. 24) - [1], in which the arm model is presented in the form of an elastic cylinder that imitates the upper third of the shoulder, on which the compression cuff of the calibrated measuring instrument is put on. Cuff pressure pulsations are created by the core of an electromagnet, made with emphasis on the elastic bottom of the cylinder, with a frequency specified by a quartz frequency generator.

Here, pressure pulsations are transmitted to the compression cuff through the entire cylinder imitating the arm, whereas in the real blood circulation process, pressure pulsations are transmitted only through the artery. It is also necessary to disconnect the compression cuff from the calibrated measuring device to connect the compression cuff and the calibrated measuring device through the connection element to the installation's 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.

A known installation for the complete calibration of measuring blood pressure and heart rate according to patent RU No. 2223031, AB 5/02, publ. 02/10/04, Bull. No. 4 - [2], in which the arm model is an elastic tube rigidly connected to the cylinder, imitating the upper third of the shoulder, and made of elastic material. The elastic tube contains an additional cylinder made of an elastic material, to which the rod of the electromagnet tightly contacts to create periodic oscillations in the elastic tube. The oscillation frequency is created by a quartz frequency generator and is controlled by a working standard pressure and frequency.

However, such a model implementation introduces an essential methodological component of the error associated with the departure from the real simulated process.

A known installation for the complete verification of measuring blood pressure and heart rate according to patent RU No. 2301020, AB 5/02, G01L 27/00, publ. 06/20/07 Bull. No. 17 - [3], in which the model of a person’s hand is an elastic tube located in the cavity of a cylinder simulating the upper third of the shoulder, on which the compression cuff of the calibrated sphygmomanometer is put on. To maintain constant pressure values in the elastic tube, a pressure regulator is provided, pulsations in which are created by a source of pressure pulsations made in the form of a pump and a variable flow generator. Pressure and oscillation frequencies are monitored by working pressure and frequency standards.

However, this model is applicable only for verification of sphygmomanometers with a cuff on the shoulder.

Closest to the claimed utility model and coinciding with the intended purpose is a human hand model for checking blood pressure and heart rate meters (Patent RU No. 87341, АВВ 5/02, G01L 27/00, publ. 10.10.09, Bull. No. 28) - [4].

This device contains two measuring modules, which are two separate cylinders that simulate the upper and lower third of the shoulder, in which elastic tubes are placed that simulate arteries in the upper and lower third of the shoulder, respectively.

In the elastic tube imitating the brachial artery of a human hand, a shut-off and bypass element is installed to constantly maintain pressure in the first measuring module. The second elastic tube additionally contains a locking and regulating element to maintain constant pressure and heart rate in the measuring module used for calibration of sphygmomanometers with cuffs in the lower third of the shoulder. The first measuring module is designed for checking blood pressure and heart rate meters with a cuff in the upper third of the shoulder, the second - for checking instruments with a cuff in the lower third of the shoulder, while the cylinder cavities are made with the possibility of their hydraulic combination. To do this, in the simulation model of the human hand provides for the installation of a connecting locking and regulating element that hydraulically combines the two cylinders. All this makes it possible to verify sphygmomanometers in the upper third of the shoulder and the lower third of the shoulder on the same device both simultaneously and separately.

However, this model is not very sensitive to changes in small pressures in the first and second measuring modules.

The technical result, the achievement of which the claimed utility model is aimed, is to increase the sensitivity and accuracy of measurement of verified means.

The technical result is achieved in that in a simulation model of a person’s hand for checking blood pressure and heart rate measuring instruments, containing a first cylinder that simulates the upper third of the shoulder, for attaching a compression cuff of the sphygmomanometer to the shoulder, in which an elastic tube with a locking-regulating element is placed , simulating the artery of the upper third of the shoulder, the second cylinder, which simulates the lower third of the shoulder, to attach the compression cuff of the sphygmomanometer to the wrist, in the otor placed an elastic tube with a locking-regulating element that simulates an artery in the lower third of the shoulder, a locking-regulating element that connects hydraulically combining the first and second cylinders, the new one is that the elastic tube of the second cylinder is made in the form of three parallel elastic tubes with locking-regulating elements, and the elastic tube of the first cylinder contains an additional locking and regulating element. The elastic tubes of the second cylinder are made of different diameters. In the bypass tube in the second cylinder, a locking and regulating element is installed.

The essence of the utility model is illustrated in figure 1, where:

1 - the first cylinder simulating the upper third of the shoulder;

2 - the second cylinder simulating the lower third of the shoulder;

3 - elastic tube simulating the artery of the upper third of the shoulder;

4 - an elastic tube simulating the artery of the lower third of the shoulder;

5 - the first locking and regulating element of the first measuring module;

6 - locking and regulating elements of the second measuring module;

7 - locking and regulating element of the second measuring module;

8 - locking regulating element of the bypass tube;

9 -. a second locking and regulating element of the first measuring module;

10 - bypass tube;

11 - a partition;

12 - locking regulating element connecting.

A hand simulation model for checking blood pressure and heart rate measuring instruments consists of two measuring modules, which are cylinders 1 and 2, made of elastic material, in which elastic tubes 3 and 4 are placed, simulating the arteries of the upper and lower third of the shoulder, respectively. Cylinders 1 and 2 are separated by a partition 11, in which a locking-regulating element connecting 12 is installed. Cylinder 1 for connecting the compression cuff of the sphygmomanometer to the shoulder contains an elastic tube simulating the artery of the upper third of the shoulder 3, in which two locking-regulating elements 5 and 9 are installed. In the cylinder 2 for attaching a compression cuff of the sphygmomanometer, an elastic tube 4 is installed on the wrist, imitating the artery of the lower third of the shoulder, with a locking-regulating element 7. The elastic tube 4 is made in the form e three parallel elastic tubes with three locking and regulating elements 6.

In order to increase the sensitivity and accuracy of the transmission of pulsations of the working fluid to the compression cuffs of the calibrated measuring instruments, different numbers of elastic tubes, respectively, are contained in cylinders 1 and 2. In an elastic tube 3 simulating the artery of the upper third of the shoulder, there are installed: a locking-regulating element 9 for accurate pressure maintenance, which allows changing the amplitude spectrum of the measuring signal in the first measuring module, and a locking-regulating element 5 for regulating the flow of working fluid.

The elastic tube 4 is made in the form of three parallel elastic tubes simulating the vessels of the lower third of the shoulder, made of various diameters in order to increase the sensitivity in the second measuring module. The locking and regulating elements 6 mounted on three parallel tubes regulate the flow rate of the working fluid and maintain the set pressure in them, which allows changing the flow resistance in the tubes, as well as simulating complex periodic oscillations of the input signal in the second measuring module.

The cylinder 2 further comprises a bypass tube 10 with a locking and regulating element 8 for regulating the flow rate in the second measuring module.

Cylinders 1 and 2 are separated by a partition 11 in which a locking and regulating element connecting 12 is installed, which performs the function of hydraulically combining cylinders 1 and 2, equalizing the corresponding pressures in cylinders 1 and 2 for more accurate transmission of pulsations of the working fluid to the compression cuffs of calibrated measuring instruments.

This device uses a serial connection of two measuring modules 1 and 2 (sections of calibration of sphygmomanometers with cuffs superimposed on the upper and lower third of the shoulder), the locking and regulating element 8 of the bypass tube 10, as well as the locking and regulating elements 6. Using adjusted in the corresponding mode locking and regulating elements 6, locking and regulating element 7 of the elastic tube 4 simulating an artery in the lower third of the shoulder, locking and regulating element 8 of the bypass tube 10 allows high With a degree of accuracy, transfer pulsations of the working fluid to the compression cuffs of the calibrated measuring instruments, simulating arterial and capillary circulation. All this allows you to accurately approximate the technical processes of measuring blood pressure and heart rate.

The device operates as follows.

In the elastic tube 3 of the first measuring module, a working fluid is pumped with a given pressure and pulsation frequency. The regulation of fluid flow and the change in the amplitude spectrum of the signal in the elastic tube 3 of the first measuring module is carried out by the locking and regulating elements 5 and 9 with the closed locking and regulating element 7.

In the second measuring module, the regulation of pressure and fluid flow in the elastic tube 4 is achieved by the locking-regulating elements 6 and 7 with the closed locking-regulating element 9, in which, in order to change the amplitude spectrum of the measuring signal and increase the sensitivity, separation into three tubes of different diameters is provided.

The working fluid flows through the tube 3, simulating the arteries of the upper third of the shoulder, and through the tube 4, simulating the arteries of the lower third of the shoulder. To change the desired pressure drop and fluid flow in the elastic tubes 3 and 4 in the second measuring module, a bypass tube 10 with a locking and regulating element 8 is provided.

In the process of fluid movement through the hydraulic system of two measuring modules, the measured pressure and heart rate are perceived by both calibrated sphygmomanometers and working pressure and frequency standards, the results of which are compared with each other (not shown in Fig. 1).

To eliminate the influence of the additional component of the measurement error of pressure and heart rate in two measuring modules, a baffle 11 is inserted between cylinders 1 and 2. A locking and regulating element connecting 12 provides a hydraulic combination of cylinders 1 and 2 for more accurate transmission of pulsations of the working fluid to compression cuffs of calibrated means measurements when checking sphygmomanometers with both a cuff on the shoulder and on the wrist, equalizing the pressure in them.

The use of three elastic tubes with locking and regulating elements makes it possible to regulate the resistance of the fluid flow in these tubes, to simulate a different spectrum of output signals, which will increase the sensitivity of the device, and also allows you to accurately approximate the technical processes of measuring blood pressure and heart rate that occur when verification, to the real processes of measuring blood pressure and heart rate in humans.

Thus, a device is proposed that can be used both for testing automated sphygmomanometers with a cuff on the shoulder, and for checking automated sphygmomanometers with a cuff on the wrist. At the same time, the solution to this device is simple in execution, simple and reliable in operation.

Claims (3)

1. A simulation model of a human hand for checking blood pressure and heart rate measuring instruments, comprising a first cylinder that simulates the upper third of the shoulder, for attaching a compression cuff of the sphygmomanometer to the shoulder, in which an elastic tube with a locking-regulating element imitating the artery of the upper third is placed shoulder, a second cylinder that simulates the lower third of the shoulder, for attaching a compression cuff of the sphygmomanometer to the wrist, in which an elastic tube with a lock is placed o-regulating element that simulates the artery of the lower third of the shoulder, a locking regulating element connecting, hydraulically combining the first and second cylinders, characterized in that the elastic tube of the second cylinder is made in the form of three parallel elastic tubes with locking and regulating elements, and the elastic tube of the first cylinder contains an additional locking and regulating element. 2. A simulation model of a person’s hand for checking blood pressure and heart rate measuring instruments according to claim 1, characterized in that the elastic tubes of the second cylinder are made of different diameters. 3. A simulation model of a human hand for checking blood pressure and heart rate measuring instruments according to claim 1, characterized in that a shut-off and control element is installed in the bypass tube of the second cylinder.