DE3816280A1 - Housing part for centrifugal pumps - Google Patents

Abstract

The invention relates to a housing part for centrifugal pumps, which comprises two shaped parts one fitted inside the other, the shaped parts having different outer diameters. At least the outer shaped part is constructed so as to be pot-shaped. An opening attached inside the bottom surface and attached concentrically with respect to the pump shaft serves as a feed or outlet opening of the stage housing. As a result of the different outer diameters of the shaped parts, a duct is formed between their side walls, the bottom surface, corresponding to the gap cross-section, of the outer pot-shaped part being provided with a variety of passage openings.

Description

The invention relates to a centrifugal pump according to the Preamble of the main claim.

From DE-PS 27 07 776 is a multi-stage centrifugal pump known in inline design, in which the Pipe connections receiving as well as the connection with a connection housing ensuring a drive motor and one of the positioning, a shaft bearing and a self-priming attachment partly several housings of pump stages are arranged. At Channels attached to the outside of the housings guide this conveying medium opposite to the conveying direction to the the pump part, from which it is attached inflows the first impeller. From the impeller of the last stage the pumped medium flows into a collecting space, which is connected to the pressure port. The individual housings the pump stages are plastic injection molded parts formed on the outside channels, lie butted against each other and in the contact surfaces O-rings are used for sealing. In addition to being expensive to use designed molds, this solution has the disadvantage a large distance between the pipe connections and the pump mounting point. This results in unfavorable Leakage-causing housing deformations.

Another type of multi-stage link pumps is the so-called pot housing pump. Here, the housing of the individual pump stages pressed tightly against each other, within a pot filled with pressurized fluid arranged and on its outside with this print acted upon. Pot housing pumps exposed to low pressures are also known as so-called tubular casing pumps. This type  however requires according to the number of each Steps of correspondingly long pot housings or Pipe housing and represents a high operational Effort.

The invention is based, for sheet metal construction producible, single or multi-stage pumps a pump housing with arranged within it, from the medium to flow around the stage housing, which at versatile use is easy to manufacture. This problem is solved according to the characteristic Part of the main claim.

Using this solution, a stage housing can be used for sectional pumps be created, which consists of at least two simply designed and nested molded parts. The floor surface of the or the cup-shaped moldings forms with your opening concentric to the pump shaft Intake or drain opening for one within the steps arranged impeller. When using two Pot-shaped molded parts lie with their bottom surfaces to each other. The two molded parts are connected by Gluing, welding, soldering, plug connection or the like a complete assembly unit is formed. The one in the distance form side walls of the molded parts running to the pump shaft a flow gap between them, depending on the location the molded parts are annular or sickle-shaped to one another is trained. As a result of the flow openings that in that part of the bottom surface of the outer molded part are attached to the flow cross-section of the flow corresponds to the gap, the flow gap in the simplest Way to return already funded medium use Find. This is particularly advantageous in those cases in which medium to be sucked in or already pumped in the area of the inlet connection must be led.  

An embodiment of the invention provides within one outer cup-shaped molded part a cylindrical Molding of smaller outer diameter, which in Sealing area of the common contact surfaces is arranged. By means of this material-saving measure can in a simple manner surrounding the stage housing Flow gap are generated.

According to a further embodiment, the opening in the Bottom surface of the or the cup-shaped moldings with in one-way or same-pointing nozzle Mistake. When using two cup-shaped molded parts these nozzles can be designed so that they are against each other lie and thus the two moldings to each other center. There is also the possibility to choose between these To leave a gap, the width of the Suction mouth dimensions of an associated impeller, which creates a double gap on the impeller in the simplest way can train. In the case of inlets pointing inwards an inlet opening for within the stage housing located impeller. In the opposite case, with the outside pointing nozzle, would be an outlet for the Stage housing are formed and at the same time an inlet Opening for an impeller downstream of the stage housing. When using only a pot-shaped molding only a simple gap between impeller and stage housing educated.

Another embodiment of the invention provides that the Bottom surface of the outer molded part is stepped and the pump shaft cutting, offset in the axial direction arranged levels. This configuration offers the Possibility of attaching sealing surfaces or chambers or premises in which sealing rings are arranged  can be. There is also the possibility of Centering the inner molded part on a shoulder of the Bottom surface of the subsequent outer molded part. At mounting the pump is therefore a reliable one Centering and sealing of the individual housing parts possible.

Further configurations of this are in the features of Claims 5 and 6 included.

In the case of a stage housing, the outer molded part with a Axially offset bottom surface to the longitudinal axis of the housing the flow openings of the annular gap are located in a plane axially offset from the floor surface.

For the installation of sealing elements and for the transfer of forces carry serve the described in claims 8 and 9 Configurations.

In those applications where the inner To take over part-centering or sealing function , further developments provide that the inner Molded part at its free side wall end with a flange surface is provided. With a suitable choice of form, there is Possibility of forming a recess for receiving a Sealing ring. For those cases where the free Side wall end of the inner molded part attached flange extend across the entire flow gap, provides the embodiment according to claim 11 that within flow openings are provided on the flange surface.

Claim 12 describes the use of sheet metal parts.

Various embodiments of the invention are shown in FIGS. 1 to 6 and are described in more detail below. All of the exemplary representations are excerpts from multi-stage link pumps, and for the sake of a better overview - with the exception of FIGS. 1 and 2 - the impellers and guide devices arranged within the stage housing have been omitted.

Fig. 1 shows a half section of three stages of a multi-stage link pump, the parts of the middle stage, which form an assembly unit in this arrangement, are shown with solid lines for clarity. An inner pot housing ( 2 ) with a smaller outer diameter is arranged within an outer, pot-shaped molded part ( 1 ), such that the bottom surfaces ( 3 , 4 ) abut one another. An opening ( 6 ) formed within the base surface ( 3 , 4 ) and concentrically arranged with the pump shaft ( 5 ) is provided with connecting pieces ( 7 , 8 ) pointing into the interior of the stage housing. The diameters were chosen so that the two molded parts ( 1 , 2 ) are centered on the connecting piece ( 7 , 8 ). The flow gap ( 11 ) thus formed between the side walls ( 9 , 10 ) of the molded parts here serves to return the medium conveyed by the impeller ( 12 ) shown in broken lines. The direction of flow of the medium is shown by arrows. The nozzles ( 7 , 8 ) protrude into the suction mouth of the impeller ( 12 ) and thus form a sealing gap. A cover ( 13 ) resting on the last stage housing closes the last stage housing and causes a reversal of the flow direction and its inflow into the flow gap ( 11 ). If the impeller and stator arrangement are reversed, the flow is reversed to the arrows shown. The nozzles ( 7 , 8 ) would then also be arranged in the opposite direction.

The transmission of forces between the individual stage housings takes place predominantly through the side walls ( 10 ) of the inner molded part ( 2 ). The bottom surface of the outer molded part ( 1 ) located in the area of the annular gap ( 11 ) has a plurality of flow openings ( 14 ) arranged distributed over the circumference. Furthermore, the bottom surface ( 3 ) of the outer molded part ( 1 ) has a shoulder in the area of the flow gap ( 11 ) so as to create a space ( 15 ). This serves to receive a sealing ring ( 16 ) which is held in position by a side wall ( 9 ) of a preceding outer molded part ( 1 ) with a shoulder ( 33 ).

A at the free end of the side wall ( 10 ) of the inner molded part ( 2 ) attached flange ( 17 ) serves to absorb forces and extends only up to the flow openings ( 14 ).

In contrast to FIG. 1, at the free end of the side wall ( 10 ), FIG. 2 has a flange ( 17 ) covering the flow channel ( 11 ), in which the through-flow openings ( 18 ) matching the through-flow openings ( 14 ) are provided. The bottom surface ( 3 ) of the outer molded part ( 1 ) is stepped and has planes ( 19, 20 ) which are offset in the axial direction. The part of the bottom surface lying in the plane ( 19 ) corresponds to the cross section of the flow gap ( 11 ), while the part of the bottom surface ( 3 ) lying in the plane ( 20 ) forms the space ( 15 ) for the sealing ring ( 16 ). The flange ( 17 ) is used for the complete chambering of the sealing ring ( 16 ). As a result of the offset of the bottom surface there is a wall surface ( 21 ) extending in the direction of the pump shaft ( 5 ), which serves to center the inner and outer molded part ( 1 , 2 ) and to center the housing parts arranged one behind the other. In the embodiment of FIG. 2, the nozzles ( 7 , 8 ) attached to the bottom surface ( 3 , 4 ) in the region of the opening ( 6 ) have a gap in which the suction mouth ( 22 ) of the impeller ( 12 ) plunges sealingly . An effective double gap can thus be produced in a simple manner. By a telescopic overlap of the nested outer mold parts ( 1 ) in connection with the flow channel ( 11 ) covering flange ( 17 ) of the inner mold part ( 2 ), there is the possibility of different high inner mold parts ( 2 ) with a constant height molded part ( 1 ) to combine. Different running and guiding devices can thus be installed within the housing part.

FIGS. 3 and 4 show embodiments in which take place the transmission of forces between the housing parts on the side walls (9) of the outer mold parts (1). For this purpose, the side wall ( 9 ) of the outer molded part ( 1 ) is provided with flange surfaces ( 23 , 24 ) serving as an attachment. Here, Fig. 3 shows inside, the housing longitudinal axis (5) facing flange (23) During the Fig. 4 the opposite surfaces forming with outwardly facing flange (23) shows. Flat seals ( 25 ) attached between the housing parts serve for sealing. Here, too, the individual parts of the housing part are centered as a result of an offset or a stepped formation of the bottom surface ( 3 ) of the molded part ( 1 ) with the side wall of the inner molded part ( 2 ). Furthermore, the cylindrical surfaces ( 26 , 27 ) formed by the offset of the bottom surface are used for centering in relation to subsequent housing parts. An additional sealing ring ( 32 ) is held by the side wall ( 10 ) of the inner molded part ( 2 ) in the area of the bottom surface ( 3 ) of the subsequent housing part.

The Fig. 5 largely corresponds to the Fig. 3 with the difference that in this case instead of a flat seal (25) has an O-ring gasket is (16) using which at one of the side wall (9) of the outer mold part (1) attached and facing inward flange surface ( 23 ). Furthermore, the opposite bottom surface of the adjacent housing part is provided with a recess ( 15 ) corresponding to the shape of the sealing ring.

FIG. 6 shows an embodiment in which the inner molded part is designed as a cylindrical molded part ( 30 ). Here it serves to form the flow channel ( 11 ) and lies sealingly against the outer cup-shaped molded part ( 1 ).

There is also the possibility of combining the molded parts shown in FIGS . 1 to 6 with their different types of centering, sealing and force-transmitting stops in a manner other than that shown.

Claims (12)

1. Housing part for centrifugal pumps for receiving an impeller and a guide device, with flow channel parts attached to the outside, characterized in that

• - that at least two molded parts ( 1 , 2 ) of different outside diameters are arranged in a sealed manner,
• - That at least the outside of the molded parts ( 1 ) is cup-shaped,
• - That the bottom surface ( 3 , 4 ) of the cup-shaped component (s ) ( 1 , 2 ) is provided with an opening ( 6 ) arranged concentrically to a pump shaft ( 5 ),
• - That between the spaced from the pump shaft ( 5 ) ver running side walls ( 9 , 10 ) of the molded parts ( 1 , 2 ) a flow gap ( 11 ) is formed and
• - That the bottom surface ( 3 ) of the outer molded part ( 1 ) in the region of the flow gap ( 11 ) is provided with flow openings ( 14 ).

2. Housing part according to claim 1, characterized in that within an outer cup-shaped molded part ( 1 ) a cylindrical molded part ( 30 ) of smaller outer diameter is arranged sealingly in the region of the common contact surfaces. 3. Housing part according to claims 1 and 2, characterized in that the opening ( 6 ) in the bottom surface ( 3 , 4 ) of the or the cup-shaped molded parts ( 1 , 2 ) with in one or the same direction connecting piece ( 7 , 8 ) is provided. 4. Housing part according to claims 1 to 3, characterized in that the bottom surface ( 3 ) of the outer molded part ( 1 ) is stepped and the pump shaft ( 5 ) intersecting, axially offset planes ( 19, 20 ). 5. Housing part according to claims 1 to 4, characterized in that the side walls ( 9 , 10 ) and / or axially extending surfaces ( 21 , 26 , 27 ) of the stepped bottom surface ( 3 ) of the outer molded part ( 1 ) as a centering - And / or sealing surfaces are formed. 6. Housing part according to claims 1 to 5, characterized in that the inner molded part ( 2 , 30 ) on its side wall ( 10 , 31 ) has centering and / or sealing surfaces ( 21 ). 7. Housing part according to claims 1 to 6, characterized in that the flow openings ( 14 ) of the outer molded part ( 1 ) in an opposite to the bottom surface ( 3 ) axially offset plane ( 19 ) are attached. 8. Housing part according to claims 1 to 7, characterized in that the outer molded part ( 1 ) has recesses ( 15 ) for receiving sealing elements ( 16 , 25 ). 9. Housing part according to claims 1 to 8, characterized in that the side wall ( 9 ) of the outer molded part ( 1 ) with the system serving flange surfaces ( 23 , 24 ) is provided. 10. Housing part according to one or more of claims 1 to 9, characterized in that the inner molded part ( 2 , 30 ) is provided on its free side wall end with a flange surface ( 17 ). 11. Housing part according to claim 10, characterized in that a flange surface covering the annular gap of the inner molded part is provided with flow openings. 12. Housing part according to one or more of claims 1 to 11, characterized by the use of Sheet metal parts.