SU1121818A2 - Device for testing artificial heart valves - Google Patents

Abstract

DEVICE FOR TESTING ARTIFICIAL VALVES OF THE HEART; avt.s. No. 919180, characterized in that, in order to increase the reliability of the test results by measuring the return leakage of the test valve, it is provided with an additional working chamber with a socket dp of the test valve, a storage tank with a discharge tube and a branch pipe, as well as an additional measuring capacity, and the chamber is connected to the pressure-pneumohydroaccumulator and accumulative capacity, the discharge pipe is connected to the additional measuring capacity, and the base of the pressure tube is located about at the level of the upper edge of the drain funnel. g (L S

Description

The invention relates to the field of medicine, namely to devices for testing artificial heart valves, and is intended to determine the test valves. . According to the main bus, No. 919180, a device for testing artificial heart valves is known, which contains a circulation loop with a working chamber for the test valve, a pressure pneumatic accumulator with a drain funnel with float and reverse valves, and a consumable pneumohydroaccumulator, a pneumatic accumulator with high receivers and low pressure and adjustable throttle control, electro-valve and control unit with setter, heart rhythm 1. This device ensures the reliability of test results with good reproducibility and the test conditions. In addition, the ease of operation and maintenance of the device and the ability to quickly reach the desired mode of operation allows it to be used when testing serial artificial heart valves. However, it does not meet the increased requirements of cardiac surgeons for the reliability of tests, in particular, it does not provide a determination of the magnitude of the return leakage from artificial heart valves. The purpose of the invention is to increase the accuracy of the test results by measuring the return leakage of the test valve. This is achieved in that the device for testing artificial heart valves is ait. No. 91918 is equipped with an additional working chamber with a socket for the test valve, a storage tank with a pressure tube and a discharge pipe, as well as an additional measuring tank. In this case, an additional working chamber is connected to the pressures of the pneumohydroaccumulator and accumulative capacity, and the bypass side is connected to the additional measuring capacity. In addition, the base of the pressure tube is located at the level of the upper edge of the drainage flange. The drawing shows a schematic diagram of the proposed device in the layout with the test artificial heart valve. A device for testing artificial heart valves contains a cir-. a cooking circuit with a working chamber 1 for the test valve 2, a consumable 3 and a pressure 4 pneumohydroaccumulators, a pneumatic platform with receivers of high 5 and low 6 pressure, electrovalves 7 and 8, adjustable throttles 9 and 10, gearboxes 11 and 12, filter 13, a source of compressed gas 14 and a valve 15, as well as a control unit with a heart rate adjuster 16. The discharge pneumohydroaccumulator 4 is equipped with a drain funnel 17 with a float 18 and a return valve 19 and is connected by a hydraulic manifold 20 to a consumable pneumohydroaccumulator 3 with a measuring capacity 2 1 through the valve 22. In addition, to the pressure pneumatic hydroaccumulator, 4 an additional working chamber 23 is connected to the socket .24 for the test valve 2, connected to storage tank 25 with a pressure pipe 26 and a discharge pipe 27 connected to the additional measuring tank 28. For To determine the magnitude of the return leakage, the test valve 2 is installed in the additional working chamber 23 in the socket 24. The second random test artificial heart valve is installed in the working chamber 1. When the valve 2 is tested in a pulsed flow mode, the pneumohydroaccumulator 3 is connected to the low pressure receiver 6 through the valve 15 and to the hydraulic line 20 through the valve 22. The signal coming from the control unit with the rhythm setting unit 16 closes the solenoid 8 and the solenoid 7 opens and connects pneumohydroaccumulator 4 to high pressure receiver 5. 5. At the same time, the pressure in pneumohydroaccumulator 4 grows at a speed regulated by the throttle 9. After reaching the required magnitude of this pressure, the valve 7 closes and Pneumohydroaccumulator remains constant. Then, the signal from the control unit with the heart rate adjuster 16 opens the solenoid 8, and the overpressure in pknemogidroakkumultora 4 drops to zero and the pressure changes to

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end of cycles. The pressure drop rate is regulated by the choke 10. When the overpressure in the pneumatic pressure accumulator 4 is zero, the test valves 2 in the working chambers 1 and 23 are opened by the action of the excess pressure and the pneumatic accumulator 3 and the pressure tube 26 with corresponding pressure. ) {the fluid flows into the pneumatic accumulator 4 and, flowing through the upper edge of the drain funnel 17, maintains the level in the working chamber 23 at the height of the base of the discharge tube 26. At the same time, the check valve 19 is closed. When the pressure in the pneumohydroaccumulator 4 rises, the test valves close. In this case, the fluid passing through the test valve in the working chamber 23, when it is closed and during the closed state, enters the pressure pipe 26 and, overflowing over the edge, flows into the storage tank 25 and out of it through the outlet pipe 27 the container 28. During this phase of the cycle, the liquid from the drain funnel 17 is displaced along the hydraulic line 20 into the pneumatic accumulator 3. At the same time, the float valve 18 restricts the outflow of liquid from the funnel 17 to the predetermined limits. Then the cycle repeats. The measured volume of fluid that has passed through the test valve 2 to the additional measuring tank 28 over several cycles determines the average value of the return leakage of the test valve. To improve the measurement accuracy, it is necessary that

The length of the cavity of the pressure tube was less than the volume of return leakage of the test valve. One test condition imposes the following

5 limitations. The height of the pressure tube 26 determines the pressure of the back pressure at which the valve under test opens when the surplus drops. pressure in pneumohydroaccumulator 4 to zero. Due to the failure of the tested valves, incorporated in medical and technical requirements, and in technical conditions, the minimum pressure of the backwater should be 3 mm-Hg. or 27 mm aq. Based on this, the height AND the pressure tube is selected in the range of 25-30 mm,.

. If the inner diameter of the pressure tube is narrowed too much, its own hydraulic resistance will influence the operation of the test valve. On this basis, the internal diameter (J of the pressure tube 26 is chosen in the range of 12–20 mm, which corresponds to (taking into account the height H of the tube). The volume of the internal cavity of the pressure tube is 3–9 cm, which is less than the inverse leakage of modern artificial heart valves, and these return leakage values are not of clinical significance.

The proposed device makes it possible to determine the magnitude of the return leaks from various heart valves in mass production, which significantly improves the quality of valves for clinical use.

Claims (1)

DEVICE FOR TESTING ARTIFICIAL HEART VALVES by; ed. R 919T80, with the fact that, in order to increase the reliability of test results by measuring the return leakage of the tested valve, it is equipped with an additional working chamber with a socket for the tested valve, a storage tank with a pressure tube and a discharge pipe as well as an additional measured capacity, with an additional working chamber connected to a pressure accumulator and a pneumatic accumulator and a storage tank, a branch pipe is connected to an additional measured capacity, and the base of the pressure tube is located at the top edge of the drain funnel. >