DE20321435U1 - Turbine pump for heating water has pump housing with integral magnet to remove particulates - Google Patents

Abstract

The turbine pump (1) for heating water has a pump housing (9) defining a chamber (12) for a turbine wheel (13). The pump housing has a magnet (19) integrated into it in the turbine wheel chamber, the spiral chamber (15) or an annular chamber (16) between these chambers. The magnet can be formed as a spacer between the magnetic bearing (19,22) of the rotor (3).

Description

The The present invention relates to a centrifugal pump with a pump housing, in a pump impeller rotates in an impeller space, the impeller space surrounded by a spiral space.

such Pumps are well known. They are used in particular in heating systems to promote used the heating water, which may also be provided with glycol additives can be. Often the heating water is with ferromagnetic Particles, for example, with iron, nickel or Kobaltpartiklen which are partly caused by oxidation of the plant components and distributed in the heating circuit.

Around damage Avoid the pump or heating system due to abrasion the ferromagnetic particles or by mixtures of ferromagnetic and stapled with them, non-magnetic solid particles occur can, you can provide filters in the heating system or the pump. conventional However, filters are only partially suitable because they are already in the clean condition, but especially with increasing duration of use a considerable flow resistance represent and thus an increased pump power require.

to Filtering of ferromagnetic abrasion or mixtures of ferromagnetic Particles and non-magnetic metallic, ceramic, textile or other solid particles from liquids Magnetic filters are still known. A problem with such Magnetic filters is, however, that they are especially at the use of permanent magnets either not at all, or just below big trouble clean or rinse or rinse, without interrupting the filtering process. For this cleaning are always very expensive constructions required.

For example, from the DE 31 23 229 A1 a magnetic filter is known in which the filter element must be washed when it has drawn a large amount of ferromagnetic particles from the fluid. Here, a first step is to demagnetize the filter element. As a next step, water is conducted past the filter element with compressed air in a direction opposite to the fluid flow to be filtered. Since the filter element is now no longer magnetized, the accumulated particles are removed from the filter element and taken by the flow of water and compressed air. This type of cleaning not only requires a high design effort, but it is particularly connected to an interruption of the delivery process of the fluid.

From the DE 31 34 861 A1 Furthermore, a magnetic filter is known in which the magnetic bodies are movably mounted for cleaning. For this purpose, the magnetic body along an enveloping body are moved into an end position in which the magnetic body is partially in the filter chamber and partially in a dirt chamber, wherein on the enveloping body at least one surrounding locking device is arranged, the adhering during the return movement of the magnetic body in its initial position particles stripping off the magnetic body. Also, this device is associated with a structurally very high cost. Not only is it expensive to manufacture, it is also susceptible to wear and therefore malfunction due to friction on the moving parts.

Furthermore, from the DE 31 46 858 a continuous magnetic filter is known in which an endless magnetic ring tube is provided, which is only a part of its circumference in the liquid to be filtered and which is rotated by driving rollers, wherein in an upper region outside the liquid to be filtered scrapers are arranged, the strip the adhering to the magnetic ring ferromagnetic particles. This device is structurally complex and associated with high costs. Due to the friction on the scrapers, this can also lead to wear and thus malfunction.

task The present invention is therefore an inexpensive to produce and easy to handle pump of the type mentioned, in a structurally simple way and with low flow resistance continuous filtering of ferromagnetic particles the subsidized liquid allows and in which a simple cleaning of the filter takes place.

These The object is achieved by a Pump solved according to claim 1. Advantageous embodiments and further developments of the invention result from the dependent ones Claims.

Essential in the inventive solution it that in the pump housing at least one magnet is integrated, which is arranged in one area is that directly or indirectly to the impeller space and / or to the spiral space and / or to one between the spiral space and adjacent the impeller space adjacent annulus.

The main advantage lies in the fact that the ferromagnetic particles are collected in a region of the pump housing, prevail in the relatively high flow rates of the pumped fluid. Therefore, the forces transferred to the particles by the flow are particularly large here. As soon as a certain amount of time comes Amount of ferromagnetic dirt particles has accumulated, these are carried away due to the shear forces of the flow with the flow and flushed into the discharge nozzle of the pump. The force applied to the dirt particles by the flow thus leads to flushing out of the adhering particles from the pump. Where appropriate, they can be collected in suitable filters, which can be made relatively coarse mesh.

On This structurally particularly simple way is a pump with a built-in magnetic filter that not only resistant to a continuous filtering can be operated, but in which also in due course an automatic cleaning or free rinse of the magnetic filter. When cleaning the filtering process is not interrupted.

The inventive centrifugal pump is inexpensive to manufacture and easy with a simple design to assemble and handle.

Especially It is advantageous if the magnet radially outside the pump impeller at the height of Spiral space or the annulus is arranged. Here prevail especially high flow rates, So that the from the flow transferred to the dirt particles personnel are particularly large for cleaning the filter.

According to one first embodiment a magnet can be ring-shaped be educated and about extend the entire circumference of the area of the pump housing. According to one alternative embodiment can Also arranged a plurality of separate magnets in this area of the pump housing be.

To a particularly preferred embodiment The invention is the pump as a canned pump or split pot pump formed, wherein an electric motor driving the pump is provided, whose rotatably connected to the pump impeller rotor as wet rotor in a wet room circulates, the over at least one connecting channel with the impeller space and / or with the spiral space and / or connected to the annular space of the pump housing and in contact with the sponsored Medium is, the stator of the motor through a canned or through a split pot from the wet room and the conveyed Medium is separated. Here, the or the magnets is advantageously either directly in the area or preferably immediately next to it arranged in the region in which the connecting channel or the connecting channels in the impeller space or open into the spiral space and / or in the annular space of the pump housing.

Especially in heating systems are common Such pumps in wet rotor design used. Here, in new electric motors often permanent magnetic materials used, due to the design the pump from the fluid bathes become. This could be located in the medium ferromagnetic particles on this as Accumulate critical areas and sustainable by abrasion to destruction the motor of the pump or block the engine. Therefore It is especially important in this Baurart, the engine compartment or wet space with its sensitive permanent magnets against contamination through the pumped medium and by any impurities contained therein.

By the solution according to the invention can in this case effective protection for reaches the engine compartment through the appropriate arrangement of magnets become. The magnets are here in the vicinity of the spiral space or the Annular space of the pump attached so that they are the ferromagnetic dirt particles accumulate before they can get into the engine compartment. A Damage to the Pump or destruction the engine by such dirt particles can therefore effectively prevented become.

Especially It is advantageous in this case if the connecting channel by a Sealing gap or formed by a labyrinth seal with multiple sealing gaps is. As a result, the engine compartment is additionally against a high fluid exchange protected to the pump room.

in this connection it is furthermore particularly advantageous if the magnet or magnets at a distance radially outside the estuary the sealing gap is arranged on the spiral space and / or on the annular space or are. Due to the prevailing high flow velocities are the forces transferred to the dirt particles so great that already after a short time with a relatively small accumulation of dirt particles a cleaning with the rinse The dirt particles from the discharge nozzle of the pump takes place.

Preferably The magnet or magnets is arranged in an area in which sufficient Space for accumulating a certain amount of ferromagnetic particles is available. In this way, the device according to the invention even with a pump at a lower speed and thus with lower Flow forces used become.

According to a further particularly preferred embodiment of the invention it is provided that the rotor is mounted axially in at least one direction by means of a magnetic bearing, wherein on the Rotor or on a fixedly connected to the rotor part rotating magnets and on the pump housing or on a permanently connected to the pump housing part associated therewith stationary magnets are arranged and wherein the fixed magnets is disposed either directly in the area or preferably immediately adjacent to the area / are in which open the connecting channel or the connecting channels in the impeller space and / or in the spiral space and / or in the annular space of the pump housing.

So can in a particularly advantageous manner, the advantages of the device according to the invention with the advantages of a magnetic bearing of the rotor, namely the Advantages of a particularly quiet and very low-friction rotor run and thus a particularly high efficiency of the pump connected be without this additional magnetic components are required. The pump can therefore be special small and inexpensive accomplished become.

Especially It is advantageous if the rotor rotates outside of the stator, wherein the circulating magnets in the outer peripheral area of the rotor are arranged. According to one alternative embodiment but it is also possible that the rotor circulating inside the stator, wherein at least one carrier element fixedly connected to the rotor, In particular, a disc is provided, on which the circumferential Magnets, in particular in the outer peripheral region, are arranged. In both cases the magnets are in the range of particularly high flow velocities and thus especially big cleaners to pull away arranged the dirt particles.

In a structurally particularly simple and inexpensive embodiment can the magnets, in particular the rotating magnets and the fixed ones Magnets may be formed by permanent magnets.

Especially However, it is also advantageous, the fixed magnets by To form electromagnets, so as to control the axial position of the rotor or to be able to regulate.

Especially It is also advantageous if the magnet or magnets by a Wall of the pump housing from the impeller space and / or from the spiral space and / or from the Annulus is separated, respectively, which are a relatively small thickness Has. Preferably, a thickness between 0.3 and 5 mm, in particular suggested by 1 mm.

Around a particularly good effectiveness of the magnetic filter device To achieve, it is particularly advantageous if the pump housing at least in the region of the magnet or in the region of the magnets, preferably however completely made of a non-magnetic or non-magnetizable material accomplished is.

Further Advantages and features of the invention will become apparent from the following Description and the embodiments illustrated in the drawings.

It demonstrate:

1 : first embodiment of a pump according to the invention,

2 : enlarged view of a section off 1 .

3 : Second embodiment of a pump according to the invention, and

4 : enlarged view of a section off 3 ,

The pumps shown in the figures 1 are designed in Naßläuferbau way, where the pump 1 driving electric motor 2 a rotor 3 has that as a wet runner in a wet room 4 circulates in the conveyed medium. The wet room 4 is through a canned pipe 5 ( 3 ) or other suitable sealants 6 ( 1 ) from the drying room 7 separated, in which the stator 8th of the electric motor 2 located.

The pump 1 has on the pump housing 9 a discharge nozzle 10 and a suction nozzle 11 , In the impeller room 12 of the pump housing 9 is the pump impeller 13 , the rotation with the motor shaft 14 of the electric motor 2 connected is.

The impeller room 12 is radially outward of a spiral space 15 surrounded by the circumference of the impeller space 12 increases in size and in the discharge nozzle 10 empties. Between the impeller room 12 and the spiral room 15 there is an annulus 16 that the transition from the impeller room 12 in the spiral room 15 forms.

An annular connecting channel 17 connects the annulus 16 with the wet room 4 , In the embodiment according to 1 includes the connection channel 17 also a labyrinth seal with two sealing gaps 18 , Via the connection channel 17 the pumped liquid is in contact with the in the wet room 4 revolving rotor 3 ,

According to the invention are in the pump housing 9 several magnets 19 arranged, located in one area 20 located indirectly over the thin housing wall 21 at the annulus 16 and the spiral space 15 borders. Although already a single magnet 19 sufficient, a particularly good filtering effect can be achieved in that several magnets 19 are arranged distributed over the circumference of the annular space or the spiral space. Also, a continuous, annular magnet 19 be used.

The magnet 19 is located at a small distance radially outside the mouth of the connecting channel 17 in the annulus 16 , Thus, radially inward and outward is about the area 20 There is enough space around where the ferromagnetic particles to be filtered out can accumulate. Once a certain number of dirt particles have accumulated, which may be formed in particular from the smallest iron, nickel or cobalt particles, they are carried away by the gravitational forces of the liquid being conveyed and with the flow through the spiral space 15 in the discharge nozzle 10 and thus from the pump 1 washed out.

In a particularly advantageous manner form the magnets 19 at the same time also a part of a magnetic axial bearing of the rotor 3 , For this purpose, the rotor 3 in the embodiment according to 1 at its outer peripheral region also magnets 22 on that the magnet 19 opposite and repel each other. This magnetic bearing 19 . 22 stores the rotor 3 with the wheel 13 thus in the 1 and 2 against a shift to the left to the pump housing 9 , In the other direction, the rotor 3 also be magnetically or by other bearing means, in particular be supported by axial plain bearings. Also it is possible the rotor 3 to store floating, being between the magenta forces of magnetic bearing 19 . 22 and the hydraulic forces adjusts a balance of power. This is in the motor housing 24 advantageously arranged a sliding disk, which faces away from the pump housing end face of the motor shaft 14 opposite. In the radial direction is the motor shaft 14 also in plain bearings 23 stored.

Between the magnets 19 and 22 is a fixed to the pump housing 9 and the motor housing 24 connected disc 25 arranged along with the two sealing gaps 18 a labyrinth seal forms the wet space 4 additionally against excessive fluid exchange with the annulus 16 guaranteed.

At the in 1 illustrated embodiment, the rotor is running 3 radially outside the stator 8th around. Thereby the magnets can 22 be arranged on a relatively large diameter, which corresponds to the diameter on which the magnets 19 in the pump housing 9 are arranged. In this case, a large diameter is advantageous, since in a radially further outward region, the conveyed liquid flows at a greater speed and thus greater rinsing forces are exerted on the accumulated ferromagnetic dirt particles.

At the in 3 illustrated embodiment, the rotor is running 3 radially inside the stator 8th around. Here, too, the largest possible diameter for the magnets 19 and 22 to reach is a disc 26 on the suction nozzle 11 opposite rear side of the pump impeller 13 on the motor shaft 14 attached. The magnets forming part of the magnetic thrust bearing 22 are here in the outer peripheral region of this disc 26 and thus lie in the pump housing 9 arranged magnets 19 across from.

On This particularly advantageous manner can the advantages of a magnetic Filtering with the advantages of a particularly quiet and low-friction magnetic storage are particularly easily connected.

Claims (15)

Centrifugal pump ( 1 ) with a pump housing ( 9 ), in which a pump impeller ( 13 ) in an impeller space ( 12 ) which runs from a spiral space ( 15 ), characterized in that in the pump housing ( 9 ) at least one magnet ( 19 ), which is in one area ( 20 ) which is directly or indirectly connected to the impeller space ( 12 ) and / or to the spiral space ( 15 ) and / or to one between the spiral space ( 15 ) and the impeller space ( 12 ) annular space ( 16 ) adjoins. Pump according to claim 1, characterized in that the magnet ( 19 ) radially outside the pump impeller ( 13 ) at the level of the spiral space ( 15 ) or the annulus ( 16 ) is arranged. Pump according to claim 1 or 2, characterized in that the magnet ( 19 ) is annular and extending over the entire circumference area ( 20 ) of the pump housing ( 9 ). Pump according to claim 1 or 2, characterized in that a plurality of separate magnets ( 19 ) in that area ( 20 ) of the pump housing ( 9 ) are arranged. Pump according to one of the preceding claims, wherein the pump ( 1 ) is designed as a canned pump or gap pot pump and a pump ( 1 ) driving electric motor ( 2 ), which is connected to the pump impeller ( 13 rotatably connected rotor ( 3 ) as wet runner in a wet room ( 4 ), the via at least one connection channel ( 17 ) with the impeller space ( 12 ) and / or with the spiral space ( 15 ) and / or with the annulus ( 16 ) of the pump housing ( 9 ) and in contact with the conveyed medium, wherein the stator ( 8th ) of the electric motor ( 2 ) through a can ( 5 ) or a containment shell from the wet space ( 4 ) and the conveyed medium, characterized in that the magnet or magnets (e) ( 19 ) in the mouth region or in an area ( 20 ) is arranged next to the mouth region in which the connecting channel ( 17 ) or the connection channels in the impeller space ( 12 ) and / or in the spiral space ( 15 ) and / or into the annulus ( 16 ) of the pump housing ( 9 ). Pump according to claim 5, characterized in that the connecting channel ( 17 ) through a sealing gap ( 18 ) or by a labyrinth seal with multiple sealing gaps ( 18 ) is formed. Pump according to claim 6, characterized in that the magnet or magnets (e) ( 19 ) at a distance radially outside the mouth of the sealing gap ( 18 ) in the spiral space ( 15 ) and / or into the annulus ( 16 ) is / are arranged. Pump according to one of the preceding claims, characterized in that the magnet or magnets (e) ( 19 ) in one area ( 20 is disposed in the space for accumulating a predetermined amount of ferromagnetic particles. Pump according to one of claims 5 to 8, characterized in that the rotor ( 3 ) axially in at least one direction by means of a magnetic bearing ( 19 . 22 ) is mounted, wherein on the rotor ( 3 ) or on a fixed to the rotor ( 3 ) part ( 26 ) rotating magnets ( 22 ) and on the pump housing ( 9 ) co-operating stationary magnets ( 19 ) are arranged, and wherein the stationary magnets ( 19 ) in the mouth region or in an area ( 20 ) is arranged next to the mouth region in which the connecting channel ( 17 ) or the connection channels in the impeller space ( 12 ) and / or in the spiral space ( 15 ) and / or into the annulus ( 16 ) of the pump housing ( 9 ). Pump according to claim 9, characterized in that the rotor ( 3 ) outside the stator ( 8th ), wherein the rotating magnets ( 22 ) in the outer peripheral region of the rotor ( 3 ) are arranged. Pump according to claim 9, characterized in that the rotor ( 3 ) within the stator ( 8th ) and at least one fixed to the rotor ( 3 ) connected carrier element ( 26 ), in particular a disc, is provided, on which the rotating magnets ( 22 ) are arranged in particular in the outer peripheral region. Pump according to one of the preceding claims, characterized in that the magnet or magnets (e) ( 19 . 22 ), where appropriate, the rotating and fixed magnets are permanent magnets. Pump according to one of claims 9 to 11, characterized in that the fixed magnets ( 19 ) Are electromagnets, by means of which the axial position of the rotor ( 3 ) and the pump impeller ( 13 ) is controllable or controllable. Pump according to one of the preceding claims, characterized in that the magnet or magnets (e) ( 19 ) through a wall ( 21 ) of the pump housing ( 9 ) from the impeller space ( 12 ) and / or from the spiral space ( 15 ) and / or from the annulus ( 16 ) having a thickness between 0.3 and 5 millimeters, preferably 1 millimeter. Pump according to one of the preceding claims, characterized in that the pump housing ( 9 ) at least in the area ( 20 ) of the magnets ( 19 ) is made of a non-magnetic or non-magentisable material.