EP0719938A1 - Travelling wave piezo electric motor for canned motor pumps with magnetic coupling - Google Patents

Abstract

The magnetic pump drive has an external rotor (6) driven by a piezo-travelling wave motor, coupled via magnets (5,7) to an internal rotor (3,4), on the opposite side of a partition wall (10) to the external rotor. The partition wall is used to separate the pumped flow medium from the drive. The external rotor may lie against the oscillatory stator (9) of the piezo-travelling wave motor, for rotation by the travelling waves at the surface of the oscillatory stator.

Description

The invention relates to a magnetic pump drive with an outer rotor driven by a motor, which drives an inner rotor via a magnetic coupling, wherein there is a gap between the outer and inner rotor, in which there is a partition that separates the medium carrying side from the dry side of the motor .

Such magnetic pump drives are well known and are used in particular for centrifugal pumps. A containment shell separates the side that carries the medium from the drive side of the pump.

The motors used today to drive pumps are mainly based on the electromagnetic principle. However, as is known, electric motors have the major disadvantage that they are complicated to manufacture and relatively large stator and rotor windings are necessary to generate high torques and develop high operating temperatures due to the electrical and magnetic losses. Due to the large dimensions of such an electric motor, based on the conventional electromagnetic principle, today's centrifugal pump drives are relatively large.

The object of the invention is therefore to provide a novel drive system for centrifugal pumps, which ensures a compact design and high functional reliability with small dimensions.

The object is achieved in that the outer rotor is driven by a piezo traveling wave motor. The great advantage of a piezo traveling wave motor compared to conventional electric motors based on the electromagnetic principle is a comparatively larger torque with the same overall volume.

It is advantageous if the outer rotor of the pump lies closely against an oscillating stator of the traveling wave motor. The direct connection of the outer rotor and the vibrating stator results in an extremely compact design and high functional reliability of the pump drive.

In order to generate the high speeds characteristic of centrifugal pumps, the outer rotor can also be connected to the piezo traveling wave motor via a gear.

It is also advantageous if the piezo elements of the piezo traveling wave motor are attached to the inside of a part comprising the outer rotor.

It is also structurally advantageous if the piezo elements are fastened to a disk, the disk abutting against rotation on the partition wall separating the medium carrying side from the dry side of the motor. The piezo elements can also be arranged directly on the pump housing. This leads to a particularly small design of the pump drive using fewer components.

The partition should advantageously lie sealingly between the pump housing and the carrier carrying the piezo elements, the partition being in particular a flat part. The partition can also be double-walled, so that a display medium is arranged between the walls of the partition, which is in contact with an external indicator, whereby any damage to the partition can be detected early.

A structurally simple design of the pump drive is obtained if a part carrying a bearing is attached or formed on the partition formed as a flat part, the bearing holding the pump impeller rotatably.

The magnets of the magnetic coupling arranged on the conveying medium-carrying side are advantageously attached to the side of the pump impeller facing the partition. This eliminates the rotor that carries the magnets, which is necessary in today's centrifugal pumps, which not only results in a weight reduction, but also a higher functional reliability of the pump. The magnets on the drive side are then, by design, attached to the side of the rotor which is advantageously designed as a disk and faces the partition.

A likewise structurally simple design of the magnetic pump drive is obtained when the rotor is pressurized by the part that closes the pump housing in the direction of the piezo elements, with a sliding or rolling bearing, in particular in the form of a plate spring, between the rotor and the part that closes the pump housing and / or a rubber washer. It is advantageous if the outer rotor is pressed with its side facing away from the pump impeller against the oscillating stator of the piezo traveling-wave motor by means of a clamping screw which extends through an axial bore of the outer rotor. The clamping screw generates the contact pressure required for a piezo traveling wave motor between the vibrating stator and the contact surface of the rotor.

Possible exemplary embodiments of a magnetic pump drive by means of a piezo traveling wave motor are explained in more detail below with reference to the drawings.

Fig. 1

Eine Kreiselpumpe mit Spalttopf und dazugehöriger Magnetkupplung, bei der der äußere Rotor mittels eines Piezo-Wanderwellenmotors angetrieben wird.

Fig. 2

Eine Kreiselpumpe, bei der die Piezo-Elemente an einer an der Trennwand anliegenden Scheibe angeordnet sind.

Fig. 3

Eine Kreiselpumpe mit Piezo-Wanderwellenmotor, bei der die einen Magnete der Magnetkupplung direkt am Laufrad befestigt sind.

Fig. 4

Eine Kreiselpumpe, bei der der Gehäusedeckel den Rotor des Piezo-Wanderwellenmotors gegen die Piezo-Elemente drückt.

Fig. 5 und 6

Eine Kreiselpumpe, bei der die Trennwand als flache Scheibe ausgebildet ist.

Fig. 7 bis 9

Eine Kreiselpumpe mit Piezo-Wanderwellenantrieb, bei dem die zylindrische Oberfläche des Rotors im Schwingstator einliegt.

Show it:

Fig. 1

A centrifugal pump with a containment can and associated magnetic coupling, in which the outer rotor is driven by a piezo traveling wave motor.

Fig. 2

A centrifugal pump, in which the piezo elements are arranged on a disc abutting the partition.

Fig. 3

A centrifugal pump with a piezo traveling-wave motor, in which one magnet of the magnetic coupling is attached directly to the impeller.

Fig. 4

A centrifugal pump in which the housing cover presses the rotor of the piezo traveling wave motor against the piezo elements.

5 and 6

A centrifugal pump in which the partition is designed as a flat disc.

7 to 9

A centrifugal pump with a piezo traveling-shaft drive, in which the cylindrical surface of the rotor lies in the oscillating stator.

FIG. 1 shows a centrifugal pump, in the housing 1 of which a pump impeller 2 is supported on a shaft 3, the shaft 3 being supported at one end by means of the bearing 13 designed as a roller bearing on the inside of the can. The inner rotor 4 arranged on the shaft 3 carries magnets 5 on its cylindrical surface, which form a magnetic coupling with the magnet 7 arranged on the outer rotor 6. The containment can 10 separates the side 22 of the pump carrying the conveying medium from the dry side 21, in which the piezo traveling wave drive is located.

The housing 1 of the pump is closed with a cover 14, the cover 14 being fastened to the housing by means of screws 15. Between the cover 14 and the housing 1 and the containment shell 10 there is a sealing part 17. The containment can 10 can be double-walled, so that between the two walls of the can 10 there is a display medium 16 which is connected to an indicator (not shown) located on the outside of the pump housing 1, 14. Due to the display medium 16 and the indicator located in the can 10, damage to the can 10 is indicated at an early stage.

By means of a clamping screw 18 and the associated nuts 19 and disc springs 20, the outer rotor 6 is pressed with its contact surface against the vibration stator 9 designed as a disc, the other side of the vibration stator 9 abutting the piezo elements 8 and the piezo elements 8 are attached to the inside of the housing cover 14. Between the nut 19 and the outer rotor 6 is a slide bearing consisting of a rubber washer 11 and a plate spring 11a.

Due to the traveling wave excited in the vibration stator 9 by the piezo elements 8, the traveling wave with its wave crests facing the rotor 6 engages in the contact layer or adhesive layer, not shown, which is attached to the rotor 6, and sets the outer rotor 6 in rotary motion. A torque is transmitted to the shaft 3 and thus to the pump impeller 2 by means of the magnetic coupling 5, 7.

FIG. 2 shows a further embodiment of a centrifugal pump with a piezo traveling shaft drive. The outer rotor 6 is now ring-shaped, with the housing cover 1 pressurizing the rotor 6 in the direction of the vibrating stator 9 and piezo elements 8. Between the housing cover 14 and the rotor 6 is a slide bearing, consisting of a rubber washer 11 and a plate spring 11a. The piezo elements 8 are arranged on a disk 23, which rests against rotation between the housing cover 1 and the separating body 10 designed as a containment shell, and deform in the axial direction due to the voltage applied to them and generate the required traveling wave in the oscillating stator 9. The outer magnets 7 of the magnetic coupling 5, 7 are arranged on the inside of the ring-shaped rotor 6.

Figure 3 shows a further embodiment of a centrifugal pump with a piezo traveling shaft drive, the piezo elements 8 being arranged on a disk 23 which is fastened in the housing cover 14 by means of screws 24 and the disk 23 by means of a tensioning screw 18 and the associated nuts 19 with their Piezo elements 8 and the vibration stator 9 is pressed firmly against the rotor 6 in the axial direction.

The containment shell 10 is designed in such a way that it has an annular recess in which the rotor 6 engages with its magnets 7 and a further central recess which is open toward the conveying medium side 22 and in which the shaft 3 carrying the impeller 2 is mounted via the bearing 13 . The magnets 5 corresponding to the magnets 7 are attached directly to the side of the impeller 2 facing the containment shell 10.

FIG. 4 shows a centrifugal pump with a piezo traveling-wave drive, in which the adhesive layer of the rotor 6 corresponding to the vibration stator 9 and the magnets 7 of the magnetic coupling 5, 7 are fastened on the side of the rotor 6 facing the pump. The housing cover 14 presses the rotor 6 by means of the screws 15 against the vibration stator 9 via a slide bearing, in particular consisting of a rubber washer 11 and a plate spring 11a. The piezo elements 8 are arranged on an annular disk 23 which is between the housing 1 and the Vibration stator 9 is inserted.

In contrast to the embodiment according to FIG. 3, the partition wall has only one recess, which holds the bearing 13, in which the shaft 3, which is rotatably connected to the pump impeller 2, is mounted.

Figure 5 shows a centrifugal pump, in which the separating body 10 is a flat disk, in particular a double-walled disk, on which a sleeve 12 is formed or fastened on the side carrying the conveying medium and has a bearing 13, in particular a roller bearing, on its inside in which the shaft 3 carrying the pump impeller 2 rotatably lies.

FIG. 6 shows a centrifugal pump in which the housing cover 14 is a flat disk which, by means of the screws 15, presses the rotor 6 against the oscillating stator 9 and the piezo elements 8 via the slide bearing 11, 11a, between the piezo elements 8 and the housing 1 of the separating body 10 lies sealingly and on the separating body 10 a body 3 is formed, which is in particular cylindrical and has a bearing 13 on its outer surface, on which the pump impeller 2 is rotatably mounted.

Figure 7 shows a centrifugal pump with a piezo traveling shaft drive, in which the piezo elements 8 lie on a cylindrical inner surface of the housing cover 14, the piezo elements 8 expanding or contracting in the radial direction by applying an external voltage, and thereby Vibrate stator 9 in resonance. The rotor 6 lies in the oscillating stator 9, which is shaped as a cylindrical sleeve, the rotor 6 with its adhesive layer located on its cylindrical surface lying in the oscillating stator 9.

The wave crests formed on the inside of the vibration stator of the traveling waves generated by the resonance engage in the contact layer or adhesive layer of the rotor 6 and set it in rotation. The magnets 7 of the magnetic coupling 5, 7 lie on the inside of the likewise sleeve-shaped rotor 6 and cooperate with the magnets 5, which are attached to the outside of the rotor 4, whereby the pump wheel is also set in rotation.

FIGS. 8 and 9 show a centrifugal pump by means of a piezo traveling wave motor, in which the magnetic coupling 5, 7 acts through a separating body 10 in the axial direction. The magnets 5 are attached to the side of the impeller 2 facing the separating body 10. The magnets 7 are arranged on the side of the disk-shaped or ring-shaped rotor 6 facing the pump impeller 2. The rotor 6 bears in whole or in part with its cylindrical surface on the vibration stator 9 formed as a sleeve with its contact layer. The piezo elements 8 lie in a ring in the housing cover 14 or the pump housing 1. The surface of the rotor 6 and the vibration stator 9 shaped as a sleeve are curved, in particular concave or convex, whereby the rotor 6 is held in the axial direction by the vibration stator 9. Either the surface of the rotor 6 or the surface shape of the vibration stator 9 can be at least partially concave or convex.

Claims (20)

Magnetic pump drive, with an outer rotor (6) driven by a motor, which drives an inner rotor (3, 4) via magnets (5, 7), with a gap between the outer and inner rotor in which a partition (10) is inserted, which separates the medium carrying side from the dry side of the motor, characterized in that the outer rotor (6) is driven by a piezo traveling wave motor. Magnetic pump drive according to claim 1, characterized in that the outer rotor (6) lies closely against an oscillating stator (9) of the traveling wave motor. Magnetic pump drive according to claim 1 or 2, characterized in that the outer rotor (6) is connected to the piezo traveling wave motor via a gear. Magnetic pump drive according to one of the preceding claims, characterized in that the piezo elements (8) of the piezo traveling wave motor are fastened to the inside of a part (14) comprising the rotor. Magnetic pump drive according to one of the preceding claims, characterized in that the piezo elements (8) are fastened to one side of a disk (23) and that the other side of the disk (23) bears against the partition (10) in a rotationally secure manner. Magnetic pump drive according to one of the preceding claims, characterized in that the piezo elements (8) are attached to the pump housing (1). Magnetic pump drive according to one of the preceding claims, characterized in that the partition (10) lies sealingly between the pump housing (1) and the carrier (14, 23) carrying the piezo elements (8). Magnetic pump drive according to one of the preceding claims, characterized in that the partition (10) is a flat part. Magnetic pump drive according to claim 8, characterized in that the partition (10) is double-walled. Magnetic pump drive according to claims 8 and 9, characterized in that between the walls of the partition (10) is a display medium (16) which is in contact with an external indicator. Magnetic pump drive according to one of Claims 8 to 10, characterized in that a part (12) carrying a bearing (13) is fastened or formed on the separating wall (10) and in that the bearing (13) rotatably holds the pump impeller (2). Magnetic pump drive according to one of the preceding claims, characterized in that the magnets (5, 7) of the magnetic coupling face each other in the axial direction. Magnetic pump drive according to one of the preceding claims, characterized in that the magnets (5) of the magnetic coupling are fastened to the side of the pump impeller (2) facing the partition (10). Magnetic pump drive according to one of the preceding claims, characterized in that the magnets (7) are attached to the side of the rotor (6) which is designed as a disk and faces the partition (10). Magnetic pump drive according to one of the preceding claims, characterized in that the rotor (6) is pressed in the direction of the piezo elements (8) by the part (14) which closes off the pump housing (1). Magnetic pump drive according to one of the preceding claims, characterized in that a sliding or roller bearing (11, 11a) is located between the rotor (6) and the part (14). Magnetic pump drive according to one of the preceding claims, characterized in that a disc spring (11) and / or a rubber disc (11a) lies between the rotor (6) and the part (14). Magnetic pump drive according to one of the preceding claims, characterized in that the clamping screw (18), which engages through an axial bore of the outer rotor (6), the rotor (6) with its side facing away from the pump impeller (2) to the oscillating stator (9 ) of the piezo traveling wave motor. Magnetic pump drive according to one of the preceding claims, characterized in that the rotor (6) is positively mounted in the axial direction by means of the oscillating stator (9). Magnetic pump drive according to claim 19, characterized in that the outer surface of the rotor (6) is at least partially concave or convex and the inner surface of the oscillating stator (9) with a concave outer surface of the rotor (6) is convex and with a convex outer surface of the rotor ( 6) is concave.

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