RU2683069C1 - Centrifugal pump for mechanical blood circulation support - Google Patents

Abstract

FIELD: medical equipment.SUBSTANCE: invention refers to medical equipment, namely to implantable devices for mechanical blood circulation support, can be used for treating the patients with terminal stage of cardiac failure. Centrifugal pump rotor pump for blood pumping with outer diameter of 20–70 mm has 2–8 tubular channels of constant cross-section with diameter of 1–6 mm. Channels are swirled on a logarithm curve by 0.4–10 turns so that the output angle of each channel from the rotor, formed by a tangent to the corresponding logarithmic curve and tangent to rotor disc outer circumference in intersection point of said curves is 1–15 degrees.EFFECT: technical result is reduced hematolysis and thrombosis.4 cl, 5 dwg

Description

The invention relates to medical equipment, namely to implantable devices for mechanical support of blood circulation, can be used for the treatment of patients with end-stage heart failure, as well as as the main pump in the systems of extracorporal auxiliary circulation.

The use of a logarithmic curve is described in a device for pumping blood (RU 2430748, C2), however, in a known device it is described for profiling a blade of an axial pump.

A device for mechanical circulation support RotaFlow, described WO 2012034569 A2. This device is a centrifugal pump, consisting of a chamber, the fluid is supplied to the inlet, and when the 4-blade rotor is closed, the fluid is pumped into the outlet tract due to centrifugal forces, creating a fluid flow rate and a pressure drop, thereby providing blood circulation support. Rotor rotation is ensured by rotation of an external magnetic field.

Due to the imperfect shape of the impeller blades, the minimization of vortex formation is insufficient, which results in hemolysis and blood thrombosis at given performance parameters. The disadvantage of this device is the hemolytic effect, which is largely associated with the blade structure of the rotating element (rotor). In view of this, the pump can only be used for short-term support of blood circulation.

The technical problem is to create a low-traumatic device for pumping blood in the form of a centrifugal pump, which provides reduced trauma of blood cells by reducing turbulence and vortex formation of blood flow.

The medical and technical result is to reduce the hemolysis and the likelihood of thrombosis in centrifugal-type devices for pumping blood at specified parameters of blood flow by reducing turbulence and vortex formation of blood flow by providing conditions for laminar blood flow with no stagnation zones when using centrifugal pump-type rotors for due to the use of the original channel geometry in them.

Thus, the medical and technical result of the claimed invention is to minimize hemolysis of blood cells and the likelihood of blood clots in the pump arising from the movement of blood in a centrifugal pump at given flow and pressure drop parameters by reducing shear stresses and blood exposure time in critical areas.

The most effective use of this device for development 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.

The proposed change in the geometry of the flow zone of the centrifugal pump rotor allows the formation of a laminar blood flow in the pump, including the pump output path, reducing the intensity and volume of the vortex zones and blood stagnation zones, as a result of which hemolysis and blood thrombosis are minimized.

The invention consists in the following.

In the rotor disk of a centrifugal pump for pumping blood with an outer diameter of 20-70 mm, 2-8 tubular channels of constant cross section with a diameter of 1-6 mm are formed (cut out). The channels are twisted along a logarithmic curve of 0.4-10 turns so that the angle of exit of each channel from the rotor, formed by a tangent to the corresponding logarithmic curve and tangent to the outer circumference of the rotor disk at the intersection of the mentioned curves, is 1-15 degrees.

The channels in the particular case have the same constant diameter for each channel.

The channels can have different diameters ranging from 1 to 6 mm.

In a particular case, 4 channels with a cross section of 5 mm each, twisted by 0.6 turns so that the exit angle of each channel from the rotor are 9 degrees, are formed (cut) in a rotor disk with an outer diameter of 46 mm.

The patented invention is an improved model for constructing a flow region of a centrifugal pump rotor. The main feature of the model is the formation of tubular spiral channels with a constant diameter in the rotation element with a variable twist geometry.

The invention is illustrated by the following figures.

In FIG. 1 shows a general isometric view of the rotor of a centrifugal type device for pumping blood with 4 channels; in FIG. 2 is a drawing of the geometry of the construction of the logarithmic curve of the tubular channel of the rotor (top view), FIG. 3-rotor with 5 channels; FIG. 4 - rotor with 4 channels; FIG. 5 - rotor with 3 channels, where:

1 - rotor;

2 - tubular channel;

3 - tangent to the outer diameter of the rotor disk at the point of flow exit;

4 - tangent to the logarithmic curve at the exit point of the stream;

α is the angle of exit of the channel from the rotor, which is determined by the tangent between the flow velocity vector at the exit point of the channel and tangent to the radial velocity vector at the same point;

D _to - the diameter of the tubular channel.

The logarithmic curve is characterized by the following parameters:

θ is the angle of deviation from zero;

r is the radius vector of the point of the spiral;

R is the radius vector of the channel exit point from the rotor.

The rotating element (rotor) (1) contains a flow zone formed by channels (2) of constant circular cross section formed along a guide curve.

The channel in diameter is a circular section formed by a logarithmic spiral. The use of a logarithmic spiral is determined by one of its properties, which consists in the fact that the angle formed by the tangent at an arbitrary point on the curve with respect to the radius vector r of the point of tangency is constant. This allows for a given diameter of the channel to obtain a constant velocity of the fluid in it.

The angle of exit of the channel from the rotor, made up by tangents to the circumference of the rotor disk (3) and tangent to the logarithmic curve (4) at the point of their intersection α, should tend to zero. This will ensure maximum coupling of the fluid flow during the transition from the rotor to the output line (cochlea and diffuser).

The diameter of the channel cross section D _k and the number of channels n depends on the total area of the exit cross sections of all channels, which should not be less than the area of the inlet S _{in of} the rotor, and also on the size of the side (radial) wall of the rotor h. The diameter of a particular channel may vary under the following conditions. Dimension compliance condition:

The number of turns of the spiral forming the channel implies a smooth flow of a unit volume of liquid due to the creation of a laminar flow in the channel of constant cross section.

In the general case, the tubular channel of the rotor has an input perpendicular to the axis of the rotor, in which the exit angle α is 90 degrees.

The angle α of the rotor channel can reach a minimum value of 1 degree.

The channel has a tangential or tangential inlet relative to the inner flowing cylindrical inlet of the rotor.

The number of channels can vary from 2 to 8.

The parameters of the spiral, such as the angle of deviation from zero θ, the coefficient of the radius of the turns a and the coefficient of the distance between the turns b vary depending on the specified overall parameters of the rotor and the channel, subject to the design points.

During the development of the pump, a centrifugal pump with a rotor was made, the flow part of which consists of four channels twisted along a logarithmic curve. The cross section of the channels has a diameter of 5 mm. The entrance to the channel has a tangent location to the input inner diameter of the rotor. The angle α is 9 degrees.

The hydrodynamic model of a centrifugal pump with a channel-type rotor was tested on a special bench. The hydrodynamic tests and tests of the simulated sample in computer-aided design systems, which consisted of comparing the hydrodynamic parameters of pumps with a channel rotor and a RotaFlow vane rotor with the same number of blades and channels, as well as the conditions for constructing the channels, confirmed a decrease in turbulent flow and a decrease in the maximum tangential stress surfaces of the rotor and centrifugal pump up to 50 Pa when using the proposed channel rotor .

Studies in computer-aided design systems of varying the angle of exit of the channel α from the rotor showed a decrease in the turbulence coefficient at values close to zero.

The results of mathematical modeling and the development of a prototype showed that due to the design of the flow zone of the rotor of the centrifugal pump in the form of tubular channels, a numerical decrease in hemolysis indicators was obtained compared to the scapular one, subject to equivalence in size and functional characteristics of the structure.

Testing of an in vitro centrifugal pump with a channel-type rotor in experiments on the study of hemolysis using donor blood showed the minimization of trauma of blood cells compared to commercial centrifugal pumps Biopump (Medtronic Inc), Rotaflow (Maquet).

The claimed invention is a new technical solution that belongs to the class of implantable technical equipment used for pumping blood and is industrially applicable, since the proposed rotor can be manufactured by medical enterprises and does not have a high manufacturing complexity.

Claims (4)

1. The rotor of a centrifugal pump for pumping blood, characterized in that in the disk with an outer diameter of 20-70 mm formed 2-8 tubular channels of constant cross section with a diameter of 1-6 mm, twisted along a logarithmic curve of 0.4-10 turns so that the angle of exit of each channel from the rotor, formed by a tangent to the corresponding logarithmic curve and tangent to the circumference of the rotor disk, is 1-15 degrees. 2. The rotor according to claim 1, characterized in that the diameters of the channels are equal. 3. The rotor according to claim 1, characterized in that the channels have different diameters ranging from 1 to 6 mm. 4. The rotor according to claim 1, characterized in that 4 channels with a diameter of 5 mm are formed in a disk with an outer diameter of 46 mm, twisted by 0.6 turns so that the exit angle of each channel from the rotor is 9 degrees.

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