EP0894196A1

EP0894196A1 - Peripheral pump

Info

Publication number: EP0894196A1
Application number: EP97920637A
Authority: EP
Inventors: Hans-Dieter Wilhelm
Original assignee: Mannesmann VDO AG; Siemens AG
Current assignee: Siemens AG
Priority date: 1996-04-18
Filing date: 1997-04-10
Publication date: 1999-02-03
Anticipated expiration: 2017-04-10
Also published as: CN1216597A; DE19615322A1; US6231300B1; AR011761A1; EP0894196B1; AU719375B2; WO1997040274A1; CN1093921C; BR9708779A; DE59707730D1; KR20000005502A; ES2180980T3; AU2694997A

Abstract

The invention relates to a peripheral pump with an impeller (2) turning in a pump case (1) and with two delivery chambers (11, 12) extending on both sides of the faces (3, 4) and each having a circular cross-section. Said delivery chambers (11, 12) have a mutual connection (13) due to overlapping of the cross-sections thereof. Consequently, the liquid can flow freely from the one delivery chamber (11) to the other delivery chamber (12). The one delivery chamber (11) has a connection with an inlet port, while the other delivery chamber (12) is connected to an outlet port.

Description

description

Peripheral pump

The invention relates to a peripheral pump with a driven impeller rotating in a pump housing, in each of which a ring of blades for conveying a liquid from an inlet duct to an outlet duct is incorporated in its end faces, and with both sides in the region of the Blades incorporated into the pump housing ring channels which, with blade chambers between the blades, form mutually opposite delivery chambers, the impeller in its radially inner region and in the region of its peripheral edge facing the pump housing to delimit a sealing gap with a small distance and which As seen in the direction of rotation, the blades rise from the central area of the impeller to the front sides.

Peripheral pumps of this type are often used to deliver fuel in a fuel tank of a motor vehicle and are therefore known. The conveyor chambers are separated from one another by a central web arranged in the middle of the impeller. When the impeller rotates, the blades in the conveying chambers generate a circulation flow running transversely to the direction of movement of the blades. This circulation flow runs from both sides of the impeller O 97/40274 ~ PC17EP97 / 01772

Side in the pump housing arranged inlet channels to the outlet channels. Between the outlet ducts and the inlet ducts, a sill is arranged in the ring ducts of the pump housing which interrupts the circulation flows. This peripheral pump is maintenance-free and has a high efficiency. The shape of the blades, which rises from the middle region of the impeller to its end faces, reduces impact losses which are caused by the liquid impinging on the front face or when the blades flow around. These shock losses always arise when the liquid to be pumped reaches the area of the impeller from the ring channels. Furthermore, this design of the blades accelerates the liquid upon entry into the ring channels to a speed which is initially higher than the speed of the blades when viewed in the direction of rotation of the impeller. The speed then decreases in the direction of rotation of the impeller, while the speed increases transversely to the direction of rotation. The circulation flows thus have a lance shape pointing in the direction of rotation of the impeller, which leads to a high delivery pressure of the peripheral pump.

A disadvantage of the known peripheral pump is that it has two inlet channels and two outlet channels. This design leads to an unnecessarily high installation effort for the peripheral pump. Furthermore, the peripheral pump has a large construction volume due to its two delivery chambers separated from one another by the central web.

Peripheral pumps with a single outlet channel and a single inlet channel, through which the liquid flows from one delivery chamber to the other delivery chamber, have already become known. The liquid flows through the impeller in a radial outer area of the blade chambers. These shapes However, processing leads to an unfavorable Zirkulationsströ- ^'mung profile, which must be guided by guide elements on the rear sides of the blades. These guide elements are also intended to reduce shock losses on the inlet side. However, these guide elements cause friction losses and take up a large proportion of the volume of the delivery chambers. As a result, the peripheral pump has a reduced delivery volume and a lower delivery pressure compared to other peripheral pumps.

The invention is based on the problem of designing a peripheral pump of the type mentioned at the outset in such a way that it has the smallest possible construction volume with a high delivery volume and at the same time has a high delivery pressure.

This problem is solved according to the invention in that a connection for overflowing the liquid is produced in the region of two mutually opposite blade chambers of the blades and in that the inlet channel is connected to one delivery chamber and the outlet channel is connected to the other delivery chamber.

As a result of this design, the peripheral pump flows axially through a first delivery chamber and a second delivery chamber and in each case has only a single inlet channel and a single outlet channel. The peripheral pump can therefore be mounted, for example, in a fuel tank with particularly little effort. The impeller does not have a central web separating the delivery chambers, so that the peripheral pump is particularly narrow. The peripheral pump according to the invention has a particularly high delivery volume, since the vane chambers are not constricted with guide elements. The friction losses within the circulation flow during a transition from the first delivery chamber to the second The conveying chamber is kept particularly small by connecting its conveying chambers. The liquid can thus flow from the first delivery chamber into the second delivery chamber almost without disturbing the circulation flow, which leads to a particularly high delivery pressure and to a particularly high efficiency of the peripheral pump according to the invention. The slight disturbance of the circulation flow has an especially advantageous effect in the case of hot liquids with a high vapor pressure, since these tend to form vapor bubbles which reduce the delivery pressure and cause cavitation damage to the impeller in the event of a disturbance or a break in the circulation flow. Furthermore, the liquid to be pumped is hardly heated thanks to the low friction losses.

If the delivery chambers have a circular cross section in the area of the blade chambers, the friction losses are particularly low.

The impact losses when the circulation flow enters the blade chambers can be kept to a minimum if, according to another advantageous development of the invention, the blades, viewed in the running direction of the impeller, are at an angle of 5 to 45 ° to the surface normal of the end faces of the impeller rise from the central area of the impeller to the respective end face.

The peripheral pump according to the invention already reaches a particularly high delivery pressure at a low rotational speed of the impeller if, according to another advantageous development of the invention, the blades, viewed in the running direction of the impeller, through an angle of 10 to 20 ° to the surface normal of the end faces of the impeller from the central region of the Rise the impeller towards the respective face. At low speeds, a lance-shaped circulation flow directed in the direction of rotation of the impeller can be generated very easily if, according to another advantageous development of the invention, the blades are seen as parabolic from the central region of the impeller to the end faces in the direction of the impeller increase.

According to another advantageous development of the invention, resonance vibrations which arise at certain speeds of the peripheral pump and viscosities of the liquids and lead to disturbing noises can be avoided simply by the blades having different angular distances from one another.

A low overall depth and simple manufacturability result if the connection is formed by an overlap of the circular conveying chambers.

The liquid flows particularly easily from the first delivery chamber into the second delivery chamber when the connection produced by overlapping the delivery chambers is expanded outwards and / or inwards in the radial direction of the impeller according to another advantageous development of the invention. This also leads to an increase in the maximum achievable delivery pressure.

The ratio of the speed of the liquid normal to the direction of circulation and the average speed in the direction of circulation to one another is decisive for the stability of the circulation flow and thus for the maximum delivery pressure that can be generated with the peripheral pump. This ratio is at a given operating point of a peripheral pump, in which the circular delivery chambers are approximately half on the blade chambers and the ring chamber. channels are divided, only depending on the ratio of the average diameter of the ring of the blades to the radius of the delivery chambers. In the case of such a peripheral pump, a high delivery pressure is achieved according to another advantageous development of the invention simply by the ratio of the mean diameter of the ring of the blades to the radius of the delivery chamber being greater than 7 and less than 99 is selected.

Experiments have led to a particularly high delivery pressure if the ratio of the mean diameter of the ring of the blades to the radius of the delivery chamber is chosen to be greater than 15 and less than 30 according to another advantageous development of the invention.

According to another advantageous further development of the invention, disturbances arising from a tearing off of the circulation flow after leaving the blade chambers are simply avoided by the edges of the blades protruding into the feed chambers being rounded off or having a chamfer.

The radius or the chamfer must only be present on the blades at the edges where the circulation flow touches the blades. The blades then have a particularly simple design if the radius or the chamfer, viewed in the running direction of the impeller, is arranged on the edge of the front of the blades in a radially outer region and on the edge of the rear in a radially inner region.

The interference-reducing effect of the radii or the width of the bevels depends essentially on the dimensions of the blades. For example, large blades need correspondingly large radii or chamfers. According to another advantageous development, the liquid circulates the invention is particularly low in interference in the delivery chambers if the radius or the width of the chamfer corresponds to at least 1/70 the height of the blades.

Axial forces acting on the impeller could press the impeller against the pump housing during operation of the peripheral pump, which would result in an increase in wear while at the same time reducing the delivery pressure. According to another advantageous development of the invention, the axial forces acting on the impeller can be easily absorbed if the impeller has a plurality of opposing depressions on its end faces and two opposing depressions are connected to one another. The depressions thus form pressure pockets of an axial plain bearing, which are connected to the delivery chambers via the sealing gaps between the impeller and the pump housing. If the liquid to be pumped leaks through the sealing gap, liquid gets into the depressions, so that the impeller floats on a liquid film during a rotational movement. These slide bearings thus prevent contact of the impeller on the pump housing during operation of the peripheral pump according to the invention.

The depressions could be arranged in a radially outer region of the impeller as seen from the blades. Here the impeller has a high peripheral speed, whereby the axial forces are absorbed when the peripheral pump starts. However, the peripheral pump is particularly space-saving if the depressions are arranged in the radially inner region of the impeller, as seen from the blades, according to another advantageous development of the invention.

Due to the high volume, the depressions have very good emergency running properties with a short-term absence of the liquid to be conveyed if the depressions are designed in the form of a trough in accordance with another advantageous development of the invention.

According to another advantageous development of the invention, the depressions are easy to produce if, according to another advantageous development of the invention, they are pocket-shaped in a tangential section through the impeller.

The impeller can be produced inexpensively if, according to another advantageous development of the invention, it is made of plastic by injection molding. Furthermore, the impeller made of plastic has a particularly low weight, as a result of which the peripheral pump very quickly reaches its maximum delivery rate after a start.

The invention permits numerous embodiments. To further clarify its basic principle, one of these is shown in the drawing and is described below. This shows in

1 shows a longitudinal section through a peripheral pump according to the invention,

2 shows a tangential section through the

Peripheral pump from Figure 1 along the line II - II,

3 shows a tangential section through the

Peripheral pump from Figure 1 along the line III - III.

FIG. 1 shows a longitudinal section of a peripheral pump according to the invention with a pump housing 1, in which - 3 -

chem an impeller 2 is rotatably arranged. In the impeller 2, a ring 5 of blades 6, 6a, 6b are incorporated in each of its two end faces 3, 4. The impeller 2 is fixed in its center on a drive shaft 7 in a rotationally fixed manner. The pump housing 1 has an annular channel 8, 9 in the area of the blades 6, 6a, 6b on both sides. The annular channels 8, 9 together with blade chambers 10, 10a, 10b shown in FIG. 2 form between the blades 6, 6a, 6b delivery chambers 11, 12, each of which has a circular cross section. When the impeller 2 rotates, circulation flows of a liquid to be conveyed arise in the conveying chambers 11, 12. For clarification, the circulation flows are marked with arrows in FIGS. 1 and 2. The delivery chambers 11, 12 are each divided in half between the vane chambers 10, 10a, 10b and the ring channels 8, 9 and have a connection 13 to one another which is produced by an overlap of their circular cross sections. Through this connection 13, liquid can flow from the one delivery chamber 11 into the other delivery chamber 12 almost without swirling.

In its radially outer region and on its end faces 3, 4, the impeller 2 is opposite the pump housing 1 by a small distance. This creates a sealing gap 14 which runs around the impeller 2 and seals the conveying chambers 11, 12.

As seen from the blades 6, 6a, 6b in the radially inner region of the impeller 2, a plurality of mutually opposite depressions 15, 16 are machined in the end faces 3, 4. In each case two opposing recesses 15, 16 are connected to one another by a channel 17. A small amount of leakage occurs through the sealing gap 14 between the impeller 2 and the pump housing 1 of the liquid to be conveyed to the depressions 15, 16. As a result, the depressions 15, 16 form axial sliding bearings for the impeller 2. When the peripheral pump is operating, the impeller 2 thus floats on a liquid film without friction.

FIG. 2 shows a tangential section through the peripheral pump according to the invention from FIG. 1 along the line II-II. To clarify the drawing, the delivery chambers 11, 12 and the impeller 2 are drawn in a stretched manner in the area of the blades 6, 6a, 6b. The pump housing 1 has an inlet channel 18 and an outlet channel 19, which are separated from one another by a sill 20 arranged on both sides of the impeller 2. The sill 20 interrupts the circulation flows of the liquid to be delivered which are generated in the delivery chambers 11, 12. The inlet channel 18 is connected to the first delivery chamber 11 directly behind the rocker 20. Seen in the direction of rotation, directly in front of the sill 20, the second delivery chamber 12 opens into the outlet channel 19.

The blades 6, 6a, 6b are arranged symmetrically in the impeller 2 and rise from an axially central region of the impeller 2 to the end faces 3, 4 of the impeller 2 by an angle α. The angle α shown here is approximately 15 °. Due to this design the flow of liquid on entry into the annular channels 8, 9 be¬ in the circumferential direction to a speed accelerates, which is initially greater than the Geschwindig¬ ness of the blades 6. siding owner ^"reduces the velocity of the liquid i: αfangsrichtung, meanwhile the speed q rises to the impeller 2. This creates a lance-shaped flow profile of the circulation flow in the ring channels 8, 9, whereby a high maximum delivery pressure can be generated. FIG. 3 shows a tangential section of the depressions 15, 16 of the impeller 2 along the line III-III from FIG. 1. The depressions 15, 16 are machined into the impeller 2 in the form of a pocket and connected to one another at their center via the channel 17.

Claims

claims

1. Peripheral pump with a driven impeller rotating in a pump housing, in each of which a ring of blades for conveying a liquid from an inlet channel to an outlet channel is incorporated in its end faces, and with both sides in the area of the blades in the pump housing incorporated ring channels, which form delivery chambers opposite one another with blade chambers between the blades, the impeller in its radially inner region and in the region of its circumferential edge facing the pump housing to limit a sealing gap at a small distance and the blades viewed in the direction of rotation Rise from the central area of the impeller to the end faces, characterized in that a connection (13) for overflowing the liquid is produced in the area of two opposing blade chambers (10, 10a) of the blades (6) and that the inlet channel

(18) with a delivery chamber (11) and the outlet channel

(19) is connected to the other delivery chamber (12).

2. Peripheral pump according to claim 1, characterized gekennzeich¬ net that the delivery chambers (11, 12) in the region of the blade chambers (10, 10a) have a circular cross-section.

3. Peripheral pump according to at least one of the preceding claims, characterized in that the blades (6) viewed in the running direction of the impeller (2) by an angle of 5 to 45 ° to the surface normal of the end faces (3, 4) of the impeller (2) from the central region of the impeller (2) to the respective end face (3 , 4) rise.

4. Peripheral pump according to claim 3, characterized gekennzeich¬ net that the blades (6) in the running direction of the impeller

(2) seen at an angle of 10 to 20 ° to the surface normal of the end faces (3, 4) of the impeller (2) from the central region of the impeller (2) to the respective end face (3, 4).

5. Peripheral pump according to claim 1, characterized gekennzeich¬ net that the blades (6) in the running direction of the impeller

(2) seen parabolically rising from the central area of the impeller (2) to the end faces (3, 4).

6. Peripheral pump according to at least one of the preceding claims, characterized in that the blades

(6) have different angular distances from each other.

7. Peripheral pump according to at least one of the preceding claims, characterized in that the connection

(13) is formed by an overlap of the circular conveying chambers (11, 12).

8. Peripheral pump according to at least one of the preceding claims, characterized in that the connection (13) produced by overlapping the delivery chambers (11, 12) is expanded in the radial direction of the impeller (2) towards the outside and / or inside .

9. Peripheral pump according to at least one of the preceding claims, in which the circular delivery chambers approximately half on the vane chambers and the Ringka- channels are divided, characterized in that the

Ratio of the mean diameter of the ring (5)

Buckets (6) to the radius of the delivery chamber (11, 12) is chosen to be greater than 7 and less than 99.

10. Peripheral pump according to claim 9, characterized gekennzeich¬ net that the ratio of the average diameter of the ring (5) of the blades (6) to the radius of the delivery chamber (11, 12) is chosen to be greater than 15 and less than 30.

11. Peripheral pump according to at least one of the preceding claims, characterized in that projecting edges of the blades (6) are rounded or have a chamfer in the delivery chambers (11, 12).

12. Peripheral pump according to claim 11, characterized gekenn¬ characterized in that the radius or the chamfer in the running direction of the impeller (2) seen on the edge of the front of the blades (6) in a radially outer region and on the edge of the rear in a radial inner area is arranged.

13. Peripheral pump according to claim 11 or 12, characterized ge indicates that the radius or the width of the chamfer corresponds to at least 1/70 the height of the blades (6).

14. Peripheral pump according to at least one of the preceding claims, characterized in that the impeller

(2) at its end faces (3, 4) a plurality of mutually gegen¬ opposite recesses (15, 16) and in each case two mutually opposite recesses (15, 16) are connected to each other ^¬.

15. Peripheral pump according to claim 14, characterized gekenn¬ characterized in that the recesses (15, 16) of the blades (6) are arranged in the radially inner region of the impeller (2).

16. Peripheral pump according to claim 14 or 15, characterized ge indicates that the recesses (15, 16) are trough-shaped.

17. Peripheral pump according to claim 14 or 15, characterized ge indicates that the recesses (15, 16) in a tan¬ potential section through the impeller (2) are pocket-shaped.

18. Peripheral pump according to at least one of the preceding claims, characterized in that the impeller

(2) is made of plastic by injection molding.