SU728864A1 - Apparatus for testing artificial heart-valves - Google Patents

Description

control 3 is driven by a pulse generator, a circulating circuit including a pressure vessel 4 - the atrium, a damper 5 imitating aortic pressure, and an adjustable choke 6 imitating peripheral resistance. The hydraulic pump 2 contains air and liquid cavities 7 and 8. A closed elastic transparent chamber 9 made of latex is placed in the liquid cavity 8 according to the configuration of the internal cavity of the left ventricle of the natural heart in the end of the systolic state with slots for installing the tested artificial valves 10 and 11 hearts. Camera 9 through the inlet connecting pipe 12 is connected to the pressure vessel 4, and through the output connecting pipe 13 to the damper 5.

The outlet nozzle 13 is made of a transparent material in the form of the ascending part and the aortic arch and has branches 14 with adjustable throttles 15 simulating the anterior, left common carotid, left subclavian and bronchial arteries, as well as the coronary arteries. The actuator, for example pneumatic, to the hydraulic pump 2 includes a filter 16, a valve 17, a gearbox 18, a high-pressure receiver 19 with a manometer 20, a high-pressure receiver 19 through an adjustable choke 21 and an electromagnetic valve 22 connected to the air chamber 7 of the hydraulic pump 2. 35 mi

These yutanas 23 and 24 have a pressure vessel 4 and a damper 5. The air cavity 7 has an outlet to the atmosphere through an adjustable choke 25 and an electromagnetic valve 26.

The device works as follows.

Before switching on the device, the pressure tank 4, the damper 5 and the elastic chamber 9 and the hydraulic pump 2 connected to them through the inlet and outlet connecting pipes 12 and 13 are filled with liquid up to a certain limit. The camera 9 is in an abbreviated state. With the help of solenoid valves 23 and 24, a high-pressure receiver 19 is connected to a pressure vessel 4 and a pressure valve 5 and 5 in them to establish pressure values corresponding to the atrial and aortic pressure. In the cavity 7, the pressure is set equal to atmospheric by means of an adjustable throttle 25

and solenoid valve 26. After (; valves 23, 24 h 26 overlap. 13 the difference in pressure difference is fluid from the pressure vessel 4 through the inlet 12 and the mitral valve 11 installed for testing enters the elastic chamber 9, which is expanded.

The signal from the pulse generator, which is installed in the control unit 3 of the drive, opens the solenoid valve 22, connecting the high-pressure receiver 19 to the air cavity 7, and the pressure in the cavities

7 and 8 of the hydraulic pump 2 increases to a value greater than the pressure in the damper 5, the elastic chamber 9 is reduced, pushing the liquid through the abrt

the valve 10 and the outlet 13 to the damper 5 and the outlets 14, from where this fluid enters the pressure vessel 4. The chamber 9 is reduced to the initial limit at which the natural heart has a geometrically similar left ventricle in a physiologically unstable state. Solenoid valve . 22 closes and valve 26 opens and in the cavity 7 of the hydraulic pump 2

atmospheric pressure is established. Then the cycle repeats.

A device for testing artificial heart valves allows for a greater flow in a living body than the known similarity of the flow flowing around the test valves in the device. As a result, the results are more reliable.

tests of artificial heart 1shapanov.

In addition, the device allows for a differentiated study of mitral and aortic artificial heart valves and their mutual interaction with multi-valve prosthetics, the study of the effect of artificial heart valves on the blood supply of the silent, left common carotid, left

poschglyuchichnoy, bronchial and coronary arteries, as well as various pathologies that occur after valve prosthetics, for example, syndrome of small minute volume.

Claims (1)

1. Copyright certificate № 388754, cl. A. 61 M 1/03, 1973