EP2181264B1 - Rotary pump - Google Patents

Description

The invention relates to a centrifugal motor pump, in particular in wet rotor design, whose electric motor rotor drives the pump impeller with its shaft and is surrounded by the motor stator, wherein the motor stator and the pump impeller are surrounded by the pump and motor housing to form a gap, and that arranged in the space at least one vibration damping element is, which stores the motor stator in the pump and motor housing

In order to reduce airborne and structure-borne noise emissions on a centrifugal motor pump, it is known to carry out vibration-damping measures on individual components, such as on the bearings or on the splitting head. It has been found that these measures are not sufficient, especially for small pumps, or are technically very expensive. Particularly difficult are the known vibration damping measures in small pumps feasible.

From the US 2,312,848 , Which corresponds to the preamble of claim 1, it is known in a centrifugal pump to arrange vibration damping elements as storage in the space between the motor stator and the outer housing.

The object of the invention is in a centrifugal motor pump of the type mentioned in a structurally simple way to reduce air and structure-borne noise emissions with high efficiency and this particular for pumps with small External dimensions. It is another object of the invention to provide a simple way electrical connections to the electric motor.

This object is achieved in that the intermediate space is partially or completely filled by an elastic molding compound as a vibration damping element.

Such a solution represents a complete decoupling of motor with impeller and the outer pump and motor housing, whereby air and structure-borne noise emissions are significantly reduced. Damping measures on individual components can be dispensed with since the entire unit is decoupled from the system. With constant precision of the components, the noise emissions can be reduced and / or with the same acoustic emission, the requirement for the precision of the components can be reduced. This can then also mean that other possibly more cost-effective engine technologies can be used. Furthermore, there is the considerable advantage that changes in the damping properties as a function of the system pressure do not arise because no forces resulting from the system pressure can act on the damping elements.

Advantageous embodiments of the inventions are listed in the subclaims. The solutions according to the invention allow for particularly simple constructions with a high damping effect, such constructions having an advantageous effect, in particular in the case of pumps of small construction.

Fig. 1

ein erstes Ausführungsbeispiel mit einer elastischen Formmasse zwischen Motorenstator und Motorgehäuse,

Fig. 2

ein zweites Ausführungsbeispiel ähnlich Figur 1 mit einem das Pumpenlaufrad umgebenden Spiralgehäuse, das vom äußeren Pumpengehäuse entkoppelt ist,

Fig. 3

ein drittes Ausführungsbeispiel als Rohrpumpe, wobei die innere Baugruppe von der Förderflüssigkeit umflossen ist,

Fig, 4

ein viertes Ausführungsbeispiel ähnlich Figur 3, wobei das Pumpenlaufrad von keinem inneren Spiralgehäuse umgeben ist.

Embodiments of the invention are illustrated in the drawings and will be described in more detail below. Show it:

Fig. 1

a first embodiment with an elastic molding compound between the motor stator and the motor housing,

Fig. 2

a second embodiment similar FIG. 1 with a spiral housing surrounding the pump impeller, which is decoupled from the outer pump housing,

Fig. 3

a third embodiment as a pipe pump, wherein the inner assembly is surrounded by the conveying fluid,

Fig. 4

a fourth embodiment similar FIG. 3 , wherein the pump impeller is surrounded by any inner volute casing.

In the four illustrated embodiments are each rotary motor pumps in wet rotor design. Here, the motor stator 17 forms a cylindrical interior 15, 18, which is traversed by the pumped liquid and in which with a motor shaft 21, a rotor 7 rotatably mounted (bearing 8). In this case, the stator 17, the space 15, 18 surrounding windings 6, which are sheathed by a thermosetting plastic or thermoplastic, so that the electric motor with its casing 11 forms a unit from which the motor shaft 21 exits into the pump chamber into it Pump impeller 5 to wear.

On both sides of the casing 11, the motor stator 17 is surrounded by an engine inner housing 19. However, this housing 19 may be missing and replaced by the casing 11. In all embodiments, the motor inner housing 19 is shown as part of the motor stator 17.

The motor stator 17 is surrounded by an outer motor housing 3 at a distance such that there is an intermediate space 22 between the stator 17 and the housing 3. The gap 22 is partially or completely filled by an elastic molding compound 12 as a vibration damping element, which decouple the stator 17 relative to the motor housing 3 and thus ensures that vibrations generated by the stator or rotor are not transmitted to the motor housing 3 substantially.

The vibration damping element may be formed by a gel. Here, the gel can form elements that are surrounded by a socket and / or a natural skin.

At the intermediate space 22 of the pump interior 20 connects to the outer pump housing 1, which is preferably designed spirally and a axial suction port 23 and an outlet opening 24 has. The liquid flowing through the pump interior 20 also flows through the gap 22 and thus flows around the motor stator 17 so that it is cooled not only via the rotor chamber 15 on the inside but also on the outside.

The outer pump housing 1 is connected to the outer motor housing 3 via flanges 2. Further, the motor connection cable 4 is guided through a seal 16 through the wall of the outer motor housing 3 to the outside.

The gap 22 is thus partially or completely filled by an elastic molding compound 12, which stores the motor stator 17 in the outer motor housing 3 damping. Here, it is preferably ensured that the elastic molding compound 12 is liquid-permeable, so that a flushing of the stator 17 takes place. Here, the molding compound may consist of an open-cell plastic foam.

The second embodiment according to Fig. 2 is different from that Fig. 1 in that the pump impeller 5 is surrounded by a spiral housing 13 that is fastened to the stator 17, in particular on the motor inner housing 19. Here, between the spiral housing 13 and the outer pump housing 1, a gap 25 which surrounds the spiral housing 13 and is connected to the intermediate space 22. In the space 25, a vibration damper 14 may be located, which is designed as a sleeve-shaped seal and bridges the inlet connection between the suction port 23 and the suction port 23 in the motor inner housing. The outlet opening 24 in the spiral housing 13 is arranged without such a seal, so that liquid emerging from the spiral housing 13 enters the intermediate spaces 22 and 25 and thus flows around the spiral housing 13 and the stator 17 on the outside. Thus, in this embodiment, the entire inner pump unit, ie drive, impeller and hydraulic part of an outer housing 1, 3 enclosed and decoupled from this via elastic elements.

The third embodiment according to Fig. 3 is different from that Fig. 2 in that the design of a tubular pump has been selected, wherein the delivery liquid flows through the intermediate space 22 in its entire quantity to an outlet opening 24, which is arranged on the other side of the motor pump coaxial with the suction opening 23. Here, the pump impeller 5 is surrounded by a spiral housing 13, so that both a gap 22 and a gap 25 is made. Again, the stator 17 is supported by vibration dampers 10, 12b. Here, the vibration damper 10 can serve as a guide of the flow.

The embodiment according to Fig. 4 again shows a tube pump and differs from the after Fig. 3 only in that a spiral housing 13 is missing.

Claims (9)

1. Centrifugal motor pump of wet rotor design, the electric motor rotor (7) of which drives the pump impeller (5) by way of its shaft (21) and is surrounded by the motor stator (17), the motor stator (17) and the pump impeller (5) being surrounded by the pump and motor housing (1, 3) with the formation of an intermediate space (22, 25), and at least one vibration-damping element (10, 12, 28) being arranged in the intermediate space (22, 25), which vibration-damping element (10, 12, 28) mounts the motor stator (17) in the pump and motor housing (1, 3), characterized in that the intermediate space (22) is filled partially or completely by an elastic moulding compound (12) as vibration-damping element.
2. Pump according to Claim 1, characterized in that the vibration-damping element is formed by a gel.
3. Pump according to Claim 2, characterized in that the gel forms elements (10) which are surrounded by a frame and/or by their own skin.
4. Pump according to one of the preceding claims, characterized in that the elastic moulding compound (12) is permeable or impermeable to liquids.
5. Pump according to one of the preceding claims, characterized in that the intermediate space (22, 25) is filled, in particular flowed through, by the pumping medium.
6. Pump according to one of the preceding claims, characterized in that the motor stator (17) is encapsulated by an electrically insulating casting compound (11) which leaves the intermediate space (22) free.
7. Pump according to one of the preceding claims, characterized in that the pump impeller (5) is surrounded by a spiral housing (13) which is surrounded by the outer pump housing (1) with the formation of the intermediate space (25).
8. Pump according to one of the preceding claims, characterized in that it is configured as a pipe pump, the pump impeller (5) delivering the pumping medium through the intermediate space (22, 25) to the outlet (24).
9. Pump according to one of the preceding claims, characterized in that the electric connector/connectors (4) is/are routed to the outside through the vibration-damping element and through the outer motor housing (3).

Images