DE102013011371A1 - Suction jet pump, in particular for a fuel delivery device - Google Patents

Abstract

The invention relates to a suction jet pump (10) for conveying a liquid suction medium by means of a liquid propellant, in particular for a fuel delivery device for conveying fuel of an internal combustion engine, comprising at least one pipe element (12), which has a mixing region through which the suction medium and the driving medium can flow in a flow direction (18) for mixing the propellant with the suction medium, wherein the tubular element (12) by two interconnected shell elements (26, 28) is formed.

Description

The invention relates to a suction jet pump, in particular for a fuel delivery device, according to the preamble of patent claim 1.

Suction jet pumps for conveying a liquid suction medium by means of a liquid propellant medium are well known from the general state of the art. Such a suction jet pump is commonly referred to as a jet pump. In such a suction jet pump or jet pump, a pumping action for conveying the suction medium is generated by a fluid jet of the propellant, wherein by means of the fluid jet by a pulse exchange, the suction medium is sucked, accelerated and compressed or promoted. By means of such a suction jet pump, the suction medium can be conveyed without moving parts of the suction jet pump, which is why the suction jet pump is particularly robust, low maintenance and versatile. The suction jet pump in this case comprises at least one pipe element which has a mixing region through which the suction medium and the blowing medium can flow in a flow direction for mixing the blowing medium with the suction medium.

An ejector pump is used, for example, in fuel conveyors for conveying fuel from internal combustion engines, in particular for motor vehicles. The use of a suction jet pump in a fuel delivery device is for example the DE 10 2007 054 857 A1 to be known as known. Both the suction medium and the propellant are liquid fuel. For providing the fluid jet of the propellant medium, the fuel is conveyed, for example, by means of a pump of the fuel delivery device, so that the liquid fuel is conveyed as a suction medium from a fuel tank into a swirl pot.

Usually, suction jet pumps have a plurality of individual components, which are produced by injection molding, for example. The suction jet pump is then assembled from the individual components. This requires a time-consuming and costly assembly process, resulting in high costs of the ejector pump.

It is therefore an object of the present invention to provide a suction jet pump, which can be produced in a particularly simple, time-consuming and cost-effective manner.

This object is achieved by a suction jet pump having the features of patent claim 1. Advantageous embodiments with expedient and non-trivial developments of the invention are specified in the remaining claims.

In order to create a suction jet pump which can be produced in a particularly simple, time-consuming and cost-effective manner, it is provided according to the invention that the tubular element is formed by two interconnected shell elements.

Preferably, the shell elements are interconnected along respective longitudinal sides extending along the flow direction. This means that the suction jet pump is designed as a longitudinally divided suction jet pump with two half-shells in the form of the shell elements. With such a longitudinal division of the suction jet pump, the tube element with the mixing region can be completely represented by the two shell elements, by the shell elements being formed separately from one another, for example, being assembled or connected to one another. The suction jet pump thus has only a very small number of parts and can be manufactured and assembled in a short time. A complex assembly process with an excessive number of components can be avoided. In addition, particularly due to the low number of parts, a particularly high efficiency of the suction jet pump can be realized.

Further advantages, features and details of the invention will become apparent from the following description of a preferred embodiment and from the drawings, which show in:

1 a schematic longitudinal sectional view of a suction jet pump to illustrate its principle of action;

2 a schematic and perspective exploded view of a suction jet pump for conveying a liquid suction medium by means of a liquid propellant, comprising a tubular element which has a flowing through the suction medium and the driving medium in a flow direction mixing region for mixing the propellant with the suction medium and is formed by two interconnected shell elements ; and

3 a schematic longitudinal sectional view of the suction jet pump according to 2 ,

In the figures, identical or functionally identical elements are provided with the same reference numerals.

1 shows one as a whole 10 designated suction jet pump for conveying a liquid Suction medium by means of a liquid propellant. The suction jet pump 10 For example, in a fuel delivery device for conveying liquid fuel of an internal combustion engine, in particular of a motor vehicle, can be used. Both the suction medium and the propellant are liquid fuel. To provide the propellant medium, the liquid fuel is conveyed for example by means of a pump of the fuel delivery device. By conveying the liquid fuel by means of the pump, a fluid jet of the propellant medium is provided, by means of which the liquid fuel can be conveyed as a suction medium.

The suction jet pump 10 , which is also commonly referred to as a jet pump, comprises a tubular element, which also serves as a mixing tube 12 referred to as. The mixing tube 12 has a whole with 14 designated channel, which in a flow direction which in 1 by a directional arrow 16 is illustrated by the suction medium and the driving medium, that is flowed through by the liquid fuel.

This shows the mixing tube 12 a mixing area 18 on, in which the driving medium is mixed with the suction medium or vice versa. The mixing area 18 is also referred to as a mixing tube area or as a mixing pipe section. How out 1 recognizable, the channel points 14 in the mixing area 18 one related to the flow direction (directional arrow 16 ) at least substantially constant, can be traversed by the fuel cross-section.

In the flow direction of the fuel through the channel 14 joins the mixing area 18 a diffuser area 20 of the mixing tube 12 at. In other words, the diffuser area 20 in the flow direction of the fuel downstream of the mixing area 18 arranged. How out 1 recognizable, the channel points 14 in the diffuser area 20 a flow cross-section widening or enlarging in the direction of flow.

Based on the flow direction is upstream of the mixing area 18 an inlet funnel area 22 of the mixing tube 12 arranged. The main medium and the driving medium flow over the inlet funnel area 22 in the mixing area 18 and finally from the mixing area 18 in the diffuser area 20 , How out 1 recognizable, the channel points 14 in the inlet funnel area 22 a flow cross-section tapering or narrowing in the flow direction.

The suction jet pump 10 also has an upstream flow direction of the inlet funnel region 22 arranged nozzle 24 or a nozzle region, via which the driving medium into the mixing tube 12 or in the channel 14 can be introduced. Starting from the nozzle 24 the propellant is first in the inlet funnel area 22 introduced, the propellant then in the mixing area 18 can flow.

Out 2 it can be seen that the suction jet pump 10 at least with respect to the mixing tube 12 is designed in shell construction. In other words, that is altogether with 12 designated pipe element by two shell elements in the form of half-shells 26 . 28 formed according to 2 shown in an exploded view and the formation of the mixing tube 12 to connect with each other or are connected. How out 2 is recognizable, are the half-shells 26 . 28 along respective longitudinal sides extending along the direction of flow 30 . 32 connected to each other or to connect with each other, so that the suction jet pump 10 is designed as a longitudinally divided suction jet pump. This allows the mixing tube 12 be made in a particularly simple, time and cost-effective manner such that the half-shells 26 . 28 assembled or assembled perpendicular to the flow direction.

As in synopsis with 3 is recognizable, is the nozzle 24 on the half shell 26 intended. In other words, the half shell forms 26 a first half of the mixing tube 12 and includes the nozzle 24 , About the nozzle 24 The driving medium is in the mixing tube 12 initiated.

The half shell 28 has an intake manifold 34 on, via which the suction medium is sucked in and into the mixing tube 12 , especially in the channel 14 , is introducible. In other words, the half shell forms 28 the second half of the mixing tube 12 and includes the intake manifold 34 , which is perpendicular or perpendicular to the longitudinal direction of the mixing tube 12 and thus to the flow direction of the mixing tube 12 extends away.

The half-shells 26 . 28 For example, are made of a plastic, in particular by injection molding, and preferably joined together by welding. This results in a compact component with only a very small number of parts, which can be produced in a simple, time-consuming and cost-effective manner.

LIST OF REFERENCE NUMBERS

10

eductor

12

mixing tube

14

channel

16

arrow

18

mixing area

20

diffuser area

22

Inlet funnel area

24

jet

26

half shell

28

half shell

30

long side

32

long side

34

intake

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102007054857 A1 [0003]

Claims (8)

Suction jet pump ( 10 ) for conveying a liquid suction medium by means of a liquid propellant, in particular for a fuel delivery device for conveying fuel of an internal combustion engine, with at least one tubular element ( 12 ), which has a mixing region through which the suction medium and the driving medium can flow in a flow direction (US Pat. 18 ) for mixing the propellant with the suction medium, characterized in that the tubular element ( 12 ) by two interconnected shell elements ( 26 . 28 ) is formed. Suction jet pump ( 10 ) according to claim 1, characterized in that the shell elements ( 26 . 28 ) along respective longitudinal sides extending along the direction of flow ( 30 . 32 ) are interconnected. Suction jet pump ( 10 ) according to one of claims 1 or 2, characterized in that one of the shell elements ( 26 . 28 ) an intake manifold ( 34 ), via which the suction medium into the tubular element ( 12 ) can be introduced. Suction jet pump ( 10 ) according to one of the preceding claims, characterized in that one of the shell elements ( 26 . 28 ) a nozzle tapering in the flow direction ( 24 ), via which the driving medium in the mixing area ( 18 ) of the tubular element ( 12 ) can be introduced. Suction jet pump ( 10 ) according to one of the preceding claims, characterized in that the tubular element ( 12 ) to the mixing area ( 18 ) subsequent diffuser area ( 20 ) having. Suction jet pump ( 10 ) according to one of the preceding claims, characterized in that the tubular element ( 12 ) in the flow direction upstream of the mixing area ( 18 ) arranged inlet funnel area ( 22 ), which tapers in the flow direction of the drive medium and the suction medium. Suction jet pump ( 10 ) according to one of the preceding claims, characterized in that the shell elements ( 26 . 28 ) are welded together. Suction jet pump ( 10 ) according to one of the preceding claims, characterized in that the shell elements ( 26 . 28 ) are made of plastic.

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