SU1028881A1 - Positive-displacement pump - Google Patents

Abstract

PUMP i benefits WECIS) Let the pumping of blood, the casing with the working chamber and the displacer placed in it, having a curvilinear surface, equidistant curvilinear surface of the end wall of the working chamber, in which the suction and-discharge nozzles with valves are made, So that, in order to reduce the degree of damage to blood elements, on the curved surface of the wall of the working chamber, a groove communicated with the discharge nozzle is performed. 2

Description

The invention relates to a pump manufacturing industry, namely, pump pumps, and can be used in medicine for pumping blood and other biological media. Volumetric pumps for blood pumping are known, which contain a working chamber, inside which there is a tubular diaphragm, and a piston, which interacts with the diaphragm by a conical end surface having an exponential generator. The pumps provide a continuous change in the speed of entry and exit of the battery. However, these pumps are characterized by a large detrimental volume of the working chamber, which reduces its flow and specific indicators. Closest to the proposed is a volumetric pump, mainly for pumping blood, comprising a housing with a working chamber and a displacer placed in it, having a curvilinear surface equidistant curvilinear surface of the end wall of the working chamber, in which the suction and discharge nozzles with valve 23 are made. In this pump, the harmful volume of the working chamber is minimized; however, due to the tight fit of the curved surface of the end stack, damage (injury) of blood elements occurs. The purpose of the invention is to reduce the degree of damage to blood elements. The goal is achieved by the fact that in a bulk pump, mainly for pumping blood, containing a housing with a working chamber and a displacer placed in it, having a curvilinear surface equidistant to the curvilinear surface of the end stack of the working chambers in which the suction and discharge nozzles with valves, on the curved surface of the end wall, the working chamber is made a groove, communicated with the discharge pipe. FIG. 1 shows a pump, a longitudinal section (section BB in FIG. 2) in FIG. 2 is a view A of FIG. one; in fig. 3 - view of the internal curvilinear surface of the end wall; in fig. 4 shows a section B-B in FIG. 3. The volumetric pump includes a housing 1 with a working chamber 2 and a displacer 3 placed in it, having a curved surface 4, an equidistant curvilinear surface 5 of the end wall b of the working chamber 2. The suction 7 and the discharge 8 nozzles with valve 9 are dispensed; and 10 respectively (suction and injection). On the curved surface 5 of the end wall b of the working chamber 2, a groove 11 is made, communicated with the discharge nozzle 8. The groove I can also be communicated with the suction nozzle 7. A thin elastic tubular diaphragm 12 is installed between the displacer 3 and the end wall 6 membrane springs 13 and 14 n are provided with an electromagnetic drive 15, which has an outer 16 and an inner 17 magnetic cores located inside the movable element 18, which is a short-lined winding and connected to the extrusion Telem 3. Inside the magnetic sensor 17 is placed 19 movement reohorrnogo tipa.Vnutrenn cavity 20 diafrag№l tube 12 communicates with the nozzles 7 and 8, pump operates as follows. When the electromagnetic drive 15 is powered by high-frequency voltage modulated with the frequency of the heart, an electromagnetic field is created that induces eddy currents in the moving element 18. The interaction of the periodic magnetic field with the eddy currents in the moving element 18 causes the latter to reciprocate axially replating the latter with the displacer 3. The displacer 3, acting on the diaphragm 12, squeezes the blood out of it, which corresponds to the heart systole, and the valve 10 is open, and valve 9 is kryvaetsa. In the extreme position, the displacer 3 lies on the curved wall b, almost completely displacing the pumped cavity from the cavity 20 of diaphragm 4y 12. Leaving the blood is collected in the groove 11, the volume of which is very small compared with the displacement of the pump. Since the blood has the ability of the displacer 3 against the wall to flow into the grooves I, there is no compression and damage to the blood elements. When the electromagitic drive is de-energized with 15 m @ 4, the selected springs 13 and 14 return the displacer 3 and the element 18 to the initial position. In the cavity 20 of the diaphragm 12 it forms: a vacuum, the discharge valve 10 is closed, sucking. valve 9 opens and blood enters cavity 20, filling it. This corresponds to the diastole of the heart. When the electromagnet drive 15 is subsequently turned on, the cycle is repeated. Turning on and off the electromagnetic actuator 15 controls the displacement sensor 19, which provides information about the position of the displacer 3. Thus, in the proposed pump, due to the presence of a curved

Claims (1)

9? EMPTY PUMP; mainly for pumping blood, comprising a housing with a working chamber and a displacer disposed therein, having a curved surface, an equidistant curved surface of the end wall of the working chamber, in which the suction and discharge nozzles with valves are made, characterized in that, in order to reduce the degree of damage blood elements, on the curved surface of the end wall of the working chamber, a groove is made, communicated with the discharge pipe.