SU1500310A1 - Auxiliary blood circulation system pump - Google Patents

Abstract

The invention relates to medical technology and can be used in implantable devices to partially or completely replace the pumping function of the heart. The aim of the invention is to increase the efficiency of an electromechanical actuator by using a motor rotor located outside the stator as a mechanical energy storage (flywheel). The motor is made with the outer rotor 5, the nut 9 is made in one piece with the outer part of the rotor 5, while the return spring 13, designed as an extension spring, is installed inside the retainer 11 and fixed at one end by the screw 7, and the other end of the bearing 14, pressed into the housing 1. The pump stores energy in the flywheel during the filling of the ventricle and releases it during the injection phase, while the electric motor runs without overload, which dramatically increases efficiency. 2 Il.

Description

3150

The invention relates to medical technology, more specifically to devices for assisted blood circulation.

The purpose of the invention is to reduce the hebarites and increase the efficiency.

FIG. 1 shows the auxiliary blood circulation pump, the longitudinal section in FIG. 2 is a section A-A in FIG. one.

The auxiliary circulation pump contains a diaphragm-type pump 2 installed in cab 1, an actuator containing a non-contact motor consisting of a stator 3 with windings A and a rotor 5 with permanent magnets 6, a screw 7 with bullets 8 entering the nut 9, made in one piece with the rotor 5, an electro magnetic coupling consisting of an inductor 10 and a clamp 11, which is included in the splines 8 of the screw 7. The clamp 11 is mounted on bearings 12, which are pressed into the housing 1. Inside the clamp 11 is installed return spring 13, working on stretching, otorrhea one end fixed for screw 7 having a retainer movable along II ,. and the other for the inner part of the bearing 14, which is pressed in the housing 1. The rotor 5 is mounted in the stator 3 on the bearings 15. On the screw 7 on the side of the pump 2 a bearing 16. The pushing plate 17 is installed with the possibility of rotation relative to the screw 7 works as follows. Under the action of the magnetic field of the stator 3, interacting with the magnetic field of the permanent magnets 6, the rotor 5 begins to rotate on the bearings 15 relative to the housing 1. When voltage is applied to the inductor 10, the latch 11 is set to the position shown in FIG. 2. Screw 7 stops rotating and nut 9 continues rotating. The screw 7 is then unscrewed from the nut 9 and moves the pushing plate 17. The force on the plate is transmitted through the subtype

16. In the pump 2, the diaphragm moves and the expulsion of the blood occurs. When performing a given number of revolutions, determined by the screw pitch (usually 8-15), the diaphragm occupies the extreme systolic position shown by the dotted line in FIG. The inductor 10 is turned off, and the screw 7 under the action of the forces of the return spring 13 begins to rotate at a speed exceeding the speed of rotation of the rotor 5, as a result of which the pushing plate 17 moves down and the pump is filled with blood. The energy of the return spring is spent on acceleration of the screw 7 with the latch 11 and overcoming the force of friction in the screw-nut pair, since the pump is filled due to the output pressure of the blood. After the completion of the filling, which is detected by the position sensor of the pushing plate, voltage is applied to the inductor 10, and the process is repeated.

Claims (1)

Invention Formula The auxiliary circulatory system pump, comprising a housing, has a diaphragm-type pump with an actuator installed in K with a drive consisting of a contactless electric motor with a stator with windings and a rotor with magnets, an inductor, a retainer, a screw with a nut, a return spring, and bearings, one of which is fixed in housing, the screw being connected to the pump, and the nut to the drive, characterized in that, in order to reduce the dimensions and increase the efficiency, the rotor is mounted outside the stator, the return spring is installed inside the retainer and fastened at one end to the screw, and the other to the inner part of the bearing in the housing, while the nut is attached to the rotor. FIG. I