RU2669985C1 - Blood pumping apparatus - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to a medical technique, namely a blood pumping apparatus, comprising a body, a rotor that is an axial impeller with blades having root and free peripheral parts, and rectifying apparatus, which are located inside the stator winding of the electric motor. On the output part of the blades, the vortex cutters are formed, in the form of cut-outs or cut-outs, the width of which is from 10 to 70 % H, and the depth in the direction of the rotation axis of the rotor is from 1 to 150 % H, where H is the height of the output edge of the blade.EFFECT: technical result consists in minimizing the hemolysis of blood elements in the axial pump, with the specified flow and pressure drop parameters.6 cl, 5 dwg

Description

The invention relates to medical equipment, namely to implantable technical devices for pumping blood and can be used as an implantable device for auxiliary blood circulation for the treatment of patients with end-stage heart failure, as well as as the main pump in systems of auxiliary intracorporeal circulation with insufficient heart function .

Known devices used for the specified purpose described in patents US 7264606, RU 2430748.

Common to these devices is the use of a pump with an axial impeller as the main element for pumping blood. Moreover, the wheel blades have a traditional design and therefore the shape of the blades in the descriptions is not specified.

The closest in technical characteristics, is the solution for US patent No. 5951263. However, due to the imperfect shape of the impeller blades, minimization of vortex formation and, as a result, hemolysis and blood thrombosis at given performance parameters is insufficient.

The technical problem is to create a device for pumping blood with an axial pump, which reduces the trauma of blood cells by reducing turbulence and vortex formation of blood flow.

The technical result consists in the prevention of hemolysis and thrombosis in blood pumping devices at specified performance parameters by reducing turbulence and vortex formation of the blood flow by providing favorable conditions for blood movement in the wake of the outlet edge of the impeller blades, which reduce the trauma of blood cells.

Thus, the technical result of the claimed invention is to minimize hemolysis of blood cells and thrombosis arising from the movement of blood in an axial pump at given flow and differential pressure parameters.

At the same time, minimal energy costs are maintained due to the minimum disturbances in the area of the output edge of the impeller, as well as minimal shear stresses. The most effective application of the development is in the design of small-sized medical devices that pump blood, as well as in pumps where minimal destruction of the pumped product is required.

We proposed to change the geometry of the outlet edge of the impeller blade of the pump, which allows us to separate and blur a single trace behind the outlet edge, thereby reducing the intensity and volume of the vortex zones in the axial pump for pumping blood, as a result of which hemolysis and blood thrombosis are minimized.

The lower intensity of the vortex flow achieved in the proposed device reduces blood damage and, as a result, reduces the likelihood of thrombosis.

The invention consists in the following.

The proposed device for pumping blood includes a housing, a rotor, which is an axial impeller with blades having root and free peripheral parts and a straightening apparatus, which are placed inside the stator winding of the electric motor. At the same time, vortex spacers are formed on the outlet part of the blades, made in the form of a cutout or notches, the width of which is from 10 to 70% N, and the depth in the direction of the axis of rotation of the rotor is from 1 to 150% N, where N is the height of the outlet edge of the blade.

In a particular case, the device for pumping blood has 2-9 cutouts in the outlet of the shoulder blades.

In the particular case, when there are two cutouts, their width is 10-40% N, and the depth of each cutout is 1-100% N.

If there are three cutouts, the width of the cuts is 10-20% N, and the depth of each cutout is 1-100% N.

Cutouts can be rectangular or triangular in shape.

The invention is illustrated by drawings.

In FIG. 1 shows a sectional view of an axial pump with modified output edges of the impeller blade; in FIG. 2 shows an isometric view of the impeller of a blood pumping device; in FIG. 3 shows a front view of the impeller with a blade (scapula) in which a notch is formed; in FIG. 4 - geometric parameters of a rectangular cutout, tied to the height of the output edge of the blade (scapula) at the final output point; in FIG. 5 - geometric parameters of a triangular cutout, tied to the height of the output edge of the blade (blades) at the final output point, where:

1 - axial pump housing;

2 - input / output fitting;

3 - sleeve;

4 - shield with pylons;

5 - impeller (rotor);

6 - straightening apparatus;

7 - rotor blades;

8 - permanent magnet;

9 - cutout on the blades;

10 - root parts of the scapula;

11 - peripheral (peripheral) parts of the scapula;

a - depth of cut;

b is the width of the cut;

H is the height of the output edge at the final trick point of the blade.

Patented axial pump, contains a housing (1), fittings (2), bushings (3), a shield with pylons (4), an impeller (5) and a straightening device (6).

Inside the housing (1) is a rotor (5), including an axial impeller with blades (7). Blades with cuts or protrusions of the output part and the edges, containing root (10) and free peripheral parts (11). The root part of the blade means the part mounted on the impeller, and the peripheral part does not contain fasteners on the maximum limiting surface of the wheel. A permanent magnet (8) is placed in the central axial part of the rotor. Moreover, the straightening apparatus (6) is located directly behind the blades (7) of the impeller (5).

The device operates as follows.

When voltage is applied to the windings of the DC motor, a rotating magnetic field is created, which, when interacting with the permanent magnets (8) built into the pump rotor (5), rotates the rotor. Blood flows through the inlet fitting (2) to the pylons of the shield (4), which is the flow guide (straightens the incoming flow), and then to the inlet of the blade (7) of the impeller (5). The shoulder blade (7) is characterized by a certain height and width. The width of the blade is a parameter (size) that determines the geometry of the blade in the direction of the impeller axis, the height is the parameter (size) that defines the geometry of the blade in the direction perpendicular to the axis of the impeller. The blade has an input edge (the starting point of its geometry (in) is one of the free ends of the blade, on which the fluid flow enters and is captured, and the output edge is the second free end of the blade (out), from which the fluid flow exits. it is also formed by fittings (2), a shield (4), a sleeve (1) and a straightening device (6).

The swirling flow emerging from the blades (7) falls on the blades of a stationary rectifier (6), which converts the kinetic energy of the rotating flow into potential energy, providing the axial direction of blood flow.

In the axial pump, at the outlet edge of the impeller vanes and the straightening apparatus, cutouts (9) are formed that are directed along the blood flow.

The fluid flow passing through the pump, behind the outlet edge of the blades, creates a single trace with reduced speeds, which creates an edge vortex. The intensity of the edge vortex is determined by the thickness and length of the outlet edge.

The cutouts at the outlet edge perform the function of dividing the vortex into a series of small vortices of lower intensity. This phenomenon is similar to a stream in the region of the outlet part of bird wings formed by feathers. That is why, for example, night owls fly almost silently, with minimal disturbances in the air and, therefore, sound vibrations.

The pump was manufactured and tested at a special bench. Tests of the inventive device with cutouts on the blades for pumping blood confirmed the necessary flow-pressure characteristics for medical use, pump performance and did not reveal a noticeable dynamic increase in hemolysis and blood thrombosis after passing through the pump duct.

The results of mathematical modeling of the range of proposed blade cutout parameters showed that in the proposed design of the impeller blade, turbulence at the outlet of the axial pump is reduced. The flow turbulence parameter for two cuts at a fixed cut depth of 50% of the height of the output edge H decreased compared with the results for the edge without cuts.

The decrease in vortex formation has the following improvements with a fixed cut-out depth of 50% of the height of the output edge H:

- for the ratio of the notch width to the height of the outlet edge H of the blades is 10%, the flow turbulence decreased by 3%.

- for the ratio of the notch width to the height of the outlet edge H of the blades is 30%, the flow turbulence decreased by 6%.

- for the ratio of the width of the cut to the height of the output edge H of the blades of 50%, the turbulence of the flow decreased by 5%.

- for the ratio of the notch width to the height of the outlet edge H of the blades is 70%, the flow turbulence decreased by 2%.

These parameters increased when the cutout depth changed from 50% to 100% and amounted to:

- for the ratio of the notch width to the height of the outlet edge H of the blades is 10%, the flow turbulence decreased by 4%.

- for the ratio of the notch width to the height of the outlet edge H of the blades is 30%, the flow turbulence decreased by 9%.

- for the ratio of the notch width to the height of the outlet edge H of the blades is 50%, the flow turbulence decreased by 7%.

- for the ratio of the notch width to the height of the outlet edge H of the blades at 70%, the flow turbulence decreased by 3%.

An increase in the number of cuts from two to four with a fixed value of the depth of cuts 50% of the height of the output edge H and a fixed value of the width of cuts 50% of the height of the output edge H gives a decrease in turbulence from 5% to 10%.

With an increase in the depth of the cut to 100% of the height of the output edge H, the value of the total width of the cuts is 50% of the height of the output edge H, with four cuts, the simulation showed a maximum decrease in turbulence by 12%.

It is worth noting that in the case of using several cutouts, the depth for each cutout can be changed taking into account the distance from the rotor axis to the permissible limits. For example, for three cuts, this assumes that the first cut from the center has a depth of 50%, the second - 75%, the third - 100%.

Testing a pump with 4 cutouts in long-term chronic animal experiments did not reveal blood clots in the pump cavities. The proposed pump belongs to the class of implantable hardware, can be manufactured by the medical industry and does not require additional costs.

Claims (6)

1. A device for pumping blood, including a housing, a rotor, which is an axial impeller with blades having root and free peripheral parts, and a straightening device, which are placed inside the stator winding of the electric motor, characterized in that vortex dissectors are formed on the outlet part of the blades, made in the form of a cut-out or cut-outs, the width of which is from 10 to 70% N, and the depth in the direction of the axis of rotation of the rotor is from 1 to 150% N, where N is the height of the outlet edge of the blade. 2. A device for pumping blood according to claim 1, characterized in that it has 2-9 cutouts in the outlet of the shoulder blades 3. A device for pumping blood according to claim 1, characterized in that in the presence of two cuts, their width is 10-40% N, and the depth of each cut is 1-100% N. 4. A device for pumping blood according to claim 1, characterized in that in the presence of three cuts, the width of the cuts is 10-20% N, and the depth of each cut is 1-100% N. 5. A device for pumping blood according to claim 1, characterized in that the cutouts are rectangular in shape. 6. A device for pumping blood according to claim 1, characterized in that the cut-outs are triangular in shape.

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