SU1405841A1 - Blood pump for artificial heart - Google Patents

Description

(21) 4105514 / 28-14

(22) 05.22.86

(46) 06.30.88. Bul No. 24

(71) Moldavian Scientific Research Institute of Cardiology

(72) M. I. Popovich and V.D. Shkilev

(53) 615.475 (088.8)

(56) USSR author's certificate

No. 1210840, cl. A 61 M 1/10, 15.02.86.

(54) BLOOD PUMP TO ARTIFICIAL HEART

(57) The invention relates to medical technology. The purpose of the invention is to reduce blood clots. The pump includes a housing 1, an inlet 2 and an outlet 3 nozzles, hydraulic actuating cavities 4 and 5 connected to sources of driven fluid. Inside the housing 1, an elastic sheath 6 is installed, which is designed with elasticity decreasing towards the outlet nozzle 3. Inside the sheath 6, there is an additional elastic sheath 7 with elasticity increasing towards the outlet nozzle. The surfaces of the shells may be coated with a non-stick adhesive. The supply of the drive fluid to the cavities 4 and 5 can be carried out by a pneumatically controlled power distributor, made in the form of a spool with two-way pneumatic control. 6 Il.

%

cl

00 4

(puez

The invention relates to medical technology, in particular to devices for replacing the natural heart

The aim of the invention is to reduce thrombosis.

FIG. 1 shows a diagram of the pump in the off position; in fig. 2 - supply of drive fluid in the hydraulic cavity; in fig. 3 — pressure supply to both hydraulic cavities; in fig. 4 shows elastic shells, completely occupying the volume of the cavity; in fig. 5 - the beginning of the compression area of the shells in the area of the inlet pipe; in fig. 6 - movement of blood to the outlet,

The pump includes a housing 1, an inlet 2 and an outlet 3 nozzles and hydraulic actuating cavities. 4 and 5, connected to sources of driving fluid (not shown). Inside the housing 1, an elastic sheath 6 is installed, which is designed with elasticity decreasing towards the outlet nozzle 3. Inside the elastic shell 6, there is an additional elastic shell 7 with elasticity increasing to the outlet nozzle, and hydraulic cavities 4 and 5, formed by both elastic shells 6 and 7, are connected independently of the source of the driven fluid.

The pump operates as follows. Initially, the driven fluid I (gas) is supplied to the hydraulic floor: cavity 4. Since the elasticity of shell 6 decreases in direction I to the outlet nozzle 3, the shell 6 completely overlaps the cross section of the housing near the inlet nozzle 2. the pressure in cavity 4, successively pressing to the inner surface of the housing 1, the shell 6 smoothly moves blood to the outlet nozzle 3. At the same time, a drive fluid is supplied to the hydraulic cavity 4 and into the cavity 5. Under The drive fluid into the cavity 5 should be carried out in such a way that the growth of the shell 7 does not keep up with the growth of the shell 6. After the shell 6 completely occupies the internal cavity of the housing 1, the pressure of the drive fluid in cavity 5 is brought to the values at which the shell 7 will also repeat the shape of the inner surface of the housing 1. The pressure in cavity 5 should

five

0

five

slightly exceed the pressure in the cavity 4. Since the elastic sheath 7 has elasticity increasing towards the outlet nozzle, the part of the sheath 7 first located at the outlet nozzle 3 expands. As the pressure in the chamber 5 increases, the driving fluid is removed from the cavity 4. On FIG. 4 shows the position at which the elastic shells 6 and 7 occupy the entire volume of the pump. The pressure in cavity 4 is absent, and the shell 6 is pressed against the inner surface of the housing 1 due to the pressure in cavity 5. When the pressure in cavity 5 is relieved (Fig. 5), the part of the shell 7 located near the inlet pipe 2 is compressed (the pressure in cavity 4 is absent), and therefore the sheath 6 is also reduced, i.e. all conditions are created for a new portion of blood to enter the pump. As the pressure in the cavity 5 is relieved, pressure is again supplied to cavity 4 (Fig. B) and the blood begins to move - c towards the outlet nozzle 3. After negative pressure drop in cavity 5, blood begins to flow. It is moved through the outlet 3 by changing the shape of the sheath 6. Then the cycle is repeated. Although in fact there are no valves in the proposed design, the functions of the valves are smoothly compressible and compressible shells 6 and 7. The surfaces of the shells may be coated with anti-adhesive. The supply of drive fluid in cavities 4 and 5 can be realized by a pneumatically controlled power distributor, made, for example, in the form of a spool with two-way pneumatic control.

Claims (1)

Invention Formula A blood pump to an artificial heart, comprising a casing, inlet and outlet nozzles, a sheath with variable elasticity, forming a hydraulically driven cavity connected to a source of driving fluid, which, in order to reduce clot formation, the elastic shells are made with decreasing in direction to the outlet nozzle by elasticity and form a hydraulically driven cavity connected to a source of driving fluid, and additional elastic sheath with elasticity increasing along the hydraulic cavity of which is connected to a source of driving fluid. fie. / fie. (para. 6