阅读说明：本技术 磁悬浮离心泵 (Magnetic suspension centrifugal pump ) 是由 N·盖利 P·丰塔尼利 E·科斯塔·马扬蒂 于 2019-10-16 设计创作，主要内容包括：磁悬浮离心泵(1),包括：一个中空本体(2),设置有用于血液的至少一个入口连接器(3)和至少一个出口连接器(4)；一个转子元件(8),容纳于所述中空本体(2)内侧并包括至少一个磁性部分(9),其中所述转子元件(8)可被与中空本体(2)相关联的定子元件命令绕着旋转轴线(X)无接触地旋转定子元件,所述转子元件(8)包括至少一个回转本体(10),所述至少一个回转本体(10)限定支撑多个桨叶(11)的上部表面,所述桨叶(11)适于将血液朝向所述出口连接器(4)输送；其中所述上部表面(12)具有大体凹面形状,并且其中所述回转本体(10)包括至少一个通孔(30),所述至少一个通孔(30)沿着所述旋转轴线(X)定位。(Magnetic levitation centrifugal pump (1) comprising: -a hollow body (2) provided with at least one inlet connector (3) and at least one outlet connector (4) for blood; -a rotor element (8) housed inside said hollow body (2) and comprising at least one magnetic portion (9), wherein said rotor element (8) is able to be commanded by a stator element associated with the hollow body (2) to rotate the stator element contactlessly about an axis of rotation (X), said rotor element (8) comprising at least one revolving body (10), said at least one revolving body (10) defining an upper surface supporting a plurality of paddles (11), said paddles (11) being adapted to convey blood towards said outlet connector (4); wherein the upper surface (12) has a substantially concave shape and wherein the swivelling body (10) comprises at least one through-hole (30), the at least one through-hole (30) being located along the rotation axis (X).)

1. Magnetic levitation centrifugal pump (1) comprising:

-at least one hollow body (2) provided with at least one inlet connector (3) and at least one outlet connector (4) for blood;

-at least one rotor element (8) housed inside said hollow body (2) and comprising at least one magnetic portion (9), wherein said rotor element (8) is commanded to rotate without contact about a rotation axis (X) by a stator element associated with said hollow body (2), said rotor element (8) comprising at least one revolving body, said at least one revolving body (10) defining an upper surface (12) supporting a plurality of paddles (11), said plurality of paddles (11) being adapted to convey blood towards said outlet connector (4);

characterized in that said upper surface (12) has a substantially concave shape and in that said swivelling body (10) comprises at least one through hole (30), said at least one through hole (30) being positioned along said rotation axis (X).

2. Pump (1) according to claim 1, characterized in that said upper surface (12) has a curved extension to define a saddle (13), said saddle (13) being adapted to receive blood entering said inlet connector (3).

3. Pump (1) according to claim 2, characterized in that said hole (30) has a first opening (30a) facing said upper surface (12).

4. Pump (1) according to claim 3, characterized in that said upper surface (12) has a coupling profile (31), said coupling profile (31) having said first opening (30 a).

5. Pump (1) according to claim 3 or 4, characterized in that said hollow body (2) has a bottom wall (20a) and said hole (30) has a second opening (30b) opposite said first opening (30a), said second opening (30b) facing said bottom wall (20 a).

6. Pump (1) according to one or more of the preceding claims, characterized by the fact that said blades (11) have a coupling profile (14) to said upper surface (12), said coupling profile (14) having a substantially curved extension.

7. Pump (1) according to claim 6, characterized in that said blades (11) have an upper profile (15) opposite said coupling profile (14), said upper profile (15) having a substantially rectilinear extension.

8. Pump (1) according to one or more of the preceding claims, characterized by the fact that said blades (11) have a coupling profile (17) of said coupling profile (14) to said upper profile (15), wherein said coupling profile (17) is projecting with respect to the overall dimensions of said swivelling body (10).

9. Pump (1) according to claim 8, characterized in that said coupling profile (17) has a curved extension.

10. Pump (1) according to one or more of the preceding claims, characterized by the fact that said paddle (11) has a rear profile (32) located between said coupling profile (14) and said upper profile (15), said rear profile (32) having a substantially rectilinear extension to separate the blood entering said hollow body (2).

11. Pump (1) according to claim 10, characterized in that said rear profile (32) extends substantially parallel to said rotation axis (X).

12. Pump (1) according to claim 10 or 11, characterized in that said rear profile (32) of said blade (11) is positioned in a radial pattern around said first opening (30 a).

13. Pump (1) according to one or more of claims 10 to 12, characterized by the fact that said rear profile (32) is opposite to said coupling profile (17).

Technical Field

The invention relates to a magnetic suspension centrifugal pump.

Background

Magnetic levitation centrifugal pumps used in the biomedical field generally comprise an internal hollow body provided with at least one blood inlet connector and at least one blood outlet connector, internally housing a rotor element provided with a plurality of paddles adapted to convey the incoming blood towards the outlet connector as a result of the rotation of the rotor element itself.

The rotor element comprises a portion of magnetic material and a stator element is located outside the hollow body, the stator element being adapted to define at least one magnetic field to lift the rotor element and control rotation of the rotor element inside the hollow body.

Further, the rotor element comprises a rotating body on which a plurality of blades is arranged in a radial pattern.

The above-mentioned blades are located on the upper part of the rotor element facing the inlet connector, which rotor element has the shape of a truncated cone.

The inclined surface of the upper part of the rotor element is intended to accompany the inlet of blood to the hollow body.

These known types of centrifugal pumps have some drawbacks.

In particular, blood entering the hollow body may be damaged due to the impact with the upper portion of the rotor element.

Another drawback is that the impact of the blood with the inclined surface of the rotor element can lead to the formation of air bubbles, which must then be removed before reintroducing the blood itself into the patient.

Some types of centrifugal pumps are known from WO 93/20860a1 and from CN 107693868 a, which, due to their configuration, do not avoid stagnation of blood inside the relative hollow body and do not optimize the ratio between the pump head and the turbulence inside them.

Disclosure of Invention

The main object of the present invention is to design a magnetically levitated centrifugal pump which reduces blood damage due to its interaction with the rotor element.

Within the scope of this aim, an object of the invention is to reduce the formation of air bubbles inside the pump itself.

Another object of the invention is to avoid stagnation of blood inside the relative hollow body.

A further object is to optimize the ratio between the pump head and its internal turbulence.

Another object of the present invention is to devise a magnetically levitated centrifugal pump which allows to overcome the aforementioned drawbacks of the prior art with a simple, rational, easy, effective to use and low cost solution.

The aforementioned object is achieved by the magnetic levitation centrifugal pump of the invention having the features of claim 1.

Drawings

Further characteristics and advantages of the invention will become more apparent from the description of a preferred but not exclusive embodiment of a magnetically levitated centrifugal pump, illustrated by way of non-limiting example, according to the list of the accompanying drawings, in which:

fig. 1 is an isometric view of a magnetically levitated centrifugal pump according to the present invention;

FIG. 2 is a cross-sectional view of the pump of FIG. 1;

FIG. 3 is an exploded view of the pump of FIG. 1;

FIG. 4 is an isometric view of a swivel body of the pump of FIG. 1;

fig. 5 is a cross-sectional view of the swivel body of fig. 4.

Detailed Description

With particular reference to these figures, reference numeral 1 indicates in its entirety a magnetically levitated centrifugal pump.

The pump 1 comprises at least one hollow body 2, the at least one hollow body 2 being provided with at least one inlet connector 3 corresponding to venous blood from the patient, and at least one outlet connector 4 corresponding to venous blood to be delivered to the blood oxygenation device.

Thus, the hollow body 2 defines a volume 7, the inlet connector 3 and the outlet connector 4 facing the volume 7, the volume 7 housing at least one rotor element 8, the at least one rotor element 8 comprising at least one magnetic portion 9.

The rotor element 8 can be commanded to rotate contactlessly about the rotation axis X by a stator element (not shown in the figures) associated with the hollow body 2. In more detail, the rotor element 8 is commanded to rotate directly by the stator, i.e. without the intervention of additional intermediate elements.

The manner in which the rotation of the rotor element 8 is controlled is, although not relevant to the present invention, widely known to the person skilled in the art.

In particular, the stator element comprises a plurality of windings intended to be crossed by an electric current to form one or more magnetic fields suitable for interacting with the rotor element 8 to cause its lifting and its rotation about the rotation axis X.

More specifically, the rotor element 8 comprises at least one revolving body 10, the at least one revolving body 10 defining an upper surface 12 supporting a plurality of paddles 11, the paddles 11 being adapted to convey blood entering the volume 7 towards the outlet connector 4.

The paddles 11 are suitably arranged in a radial pattern on the upper surface 12.

According to the invention, the upper surface 12 has a substantially concave shape and the swivelling body 10 has a through-hole 30, the through-hole 30 being positioned along the rotation axis X.

In particular, venous blood entering the volume 7 through the inlet connector 3 meets the paddle 11; and when one part passes through the hole 30, another part contacts the upper surface 12 and is conveyed towards the outlet connector 4 due to the rotation of the paddle 11.

Advantageously, the upper surface 12 has a curved extension to define a saddle 13, the saddle 13 being adapted to receive blood entering the inlet connector 3.

Thus, a portion of the blood entering inside the volume 7 contacts the upper surface 12, the curved shape of the upper surface 12 being accompanied by a slope thereon, preventing it from being flung away from the rotor element 8 due to the impact, thus reducing the risk of damage to the blood itself.

Thus, the holes 30 allow recirculation of the portion of blood entering the volume 7, avoiding the phenomenon of stagnation of blood.

More particularly, the bore 30 has a first opening 30a facing the upper surface 12.

Suitably, the upper surface 12 has a coupling profile 31, the coupling profile 31 having a first opening 30 a.

The hole 30 then has a second opening 30b opposite the first opening 30a, the second opening 30b facing the bottom wall 20a of the hollow body 2.

Conveniently, the paddle 11 has a coupling profile 14 for coupling to the upper surface 12, which profile also has a substantially curved extension to join the upper surface itself and facilitate the flow of blood.

Preferably, the blade 11 has an upper profile 15 opposite the coupling profile 14, the upper profile 15 having a substantially rectilinear extension (i.e. except for machining tolerances).

Advantageously, the blade 11 has a coupling profile 17 coupling the profile 14 with the upper profile 15, wherein the coupling profile 17 protrudes from the overall dimensions of the swivelling body 10. The term "overall dimension" of the rotating body 10 means the extension of the rotating body 10 transverse to the axis of rotation X.

The coupling profile 17 protrudes from the overall dimensions of the swivel body 10 to define a large surface area impact with blood. In the preferred embodiment shown in the figures, the coupling profile 17 has a curvilinear extension.

The blade 11 also has a rear profile 32, the rear profile 32 being located between the coupling profile 14 and the upper profile 15, the rear profile 32 having a substantially rectilinear extension (i.e. except for machining tolerances and with the ends connected to the adjacent profiles).

Advantageously, the rear profile 32 extends parallel to the rotation axis X.

The shape of the rear profile 32 allows the blood flow entering the volume 7 to be divided into two portions, one portion being conveyed into the aperture 30 and the other portion being conveyed along the upper wall 12.

The rear profile 32 is located on the opposite side of the coupling profile 17 of the relative blade 11.

The rear profile 32 of the blade 11 is then positioned in a radial pattern around the first opening 30a of the hole 30.

The swivel body 10 is provided with a housing base 18 defined at a bottom portion, the magnetic portion 9 is inserted inside the housing base 18, and a lower portion of the housing base 18 is closed by a holding member 19.

The magnetic portion 9 is arranged around the hole 30.

The hollow body 2 comprises at least one lower element 5 and at least one upper element 6, which are separate from each other and are mutually coupled.

Furthermore, the lower element 5 has a housing seat 20, the housing seat 20 being adapted to house at least a portion of the swivelling body 10, the housing seat 20 defining a bottom wall 20 a. The bottom wall 20a is provided with a guide member 20b defined at the rotation axis X for centering of the rotor element 8.

Advantageously, the upper element 6 has at least one peripheral flange 21 for coupling to the lower element 5 and at least one substantially dome-shaped body 22, the dome-shaped body 22 projecting from the peripheral flange 21, wherein the outlet connector 4 is associated with the dome-shaped body 22.

Preferably, the peripheral flange 21 defines with the lower element 5 a coupling surface 21a and the outlet connector 4 is raised with respect to the coupling surface 21 a.

In the illustrated embodiment, the coupling surface 21a is generally flat.

An air space 29 is defined between the outlet connector 4 and the peripheral flange 21, inside which air space 29 fastening means can be inserted to fasten the upper element 6 and the lower element 5 during the welding operation.

Suitably, the sealing means 26 are located between the coupling surface 21a and the lower element 5.

Advantageously, the inlet connector 3 and the outlet connector 4 are substantially elongated in shape.

In the particular embodiment shown in the figures, the inlet connector 3 is located at the top of the upper element 6 and extends coaxially with the rotation axis X.

Conveniently, the upper element 6 and the lower element 5 are provided with relative centering means 23, the centering means 23 being adapted to ensure their correct mutual positioning.

In more detail, the centering means 23 comprise at least one upper protrusion 24 defined on one of the coupling surface 21a or the lower element 5 and at least one recess 25 defined on the other of the lower element 5 or the coupling surface 21a, wherein the protrusion 24 is adapted to be inserted in the recess 25 after positioning the upper element 6 on the lower element 5.

In the particular embodiment shown in the figures, the upper element 6 and the lower element 5 have a substantially circular cross section, so that the recess 25 and the protrusion 24 have a substantially annular extension.

Although not part of the invention, the figures also show the covering element 27 of the stator element mentioned above (which is intended to support the hollow body 2), and the anchoring element 28 of the hollow body 2 to the covering element 27.

In practice it has been found that the described invention achieves the intended aim; and in particular to emphasize that the generally concave shape of the upper surface allows reducing the risk that blood may suffer damage due to impact with the revolving body.

Furthermore, the presence of the saddle means that the trajectory followed by the blood is linear, reducing the formation of air bubbles inside it compared to pumps of known type.