DE102010041990A1 - Fuel conveying unit for combustion engine of motor car, has radial inner recess and radial outer recess that are interconnected by channel in push plate, where inner and outer recesses are in fluid connection with outlet of unit - Google Patents

Abstract

The unit has a pump rotor (22) eccentrically rotated in a recess (36) of an intermediate plate (34) and comprising periphery grooves. A pumping chamber (14) is limited by a suction plate (40) in axial direction, and a push plate is limited in radial direction by the intermediate plate. A radial inner recess (35) and a radial outer recess (33) are interconnected by a channel in the push plate during pumping between the recesses for pressure equalization, where the inner and outer recesses are in fluid connection with an outlet of the unit.

Description

FIELD OF THE INVENTION

The invention relates to an aggregate for conveying fuel according to the preamble of claim 1.

STATE OF THE ART

In the DE 103 33 190 A1 as well as in the DE 101 15 866 A1 are described units for conveying fuel. These units have a drive motor and a pump part, which are typically arranged in a common housing. The pump part has a pump rotor arranged in a pump chamber and driven by the drive motor. The pump rotor has distributed over its circumference a plurality of radial grooves, in each of which a displacement element, for example in the form of a roller is guided radially movable. The pump chamber is limited in the direction of the axis of rotation of the pump rotor on the one hand by a suction plate and the drive motor through a pressure plate. In the radial direction with respect to the axis of rotation of the pump rotor, the pump chamber is delimited by an intermediate plate which has a recess formed eccentrically to the axis of rotation of the pump rotor, in which the conveying elements roll at least indirectly. In this case, a fluid can be sucked in on a suction side of the unit, be compressed by the rotating pump rotor and be discharged at an outlet side of the unit under pressure.

Such an aggregate is also known as a roller-cell pump.

However, it has been observed that such fuel delivery units, as used for example in motor vehicles, can have a considerable noise development.

DISCLOSURE OF THE INVENTION

In contrast, the aggregate for conveying fuel proposed according to the invention in an embodiment which is easy to implement can be designed to avoid excessive generation of noise during pumping.

According to one aspect of the present invention, an aggregate for conveying fuel with a drive motor and a pump part is proposed. The pump part in this case has a pump rotor, which is arranged in a pump chamber and is driven in rotation by the drive motor. The pump rotor has distributed over its circumference a plurality of radial grooves. In the grooves in each case a displacement element is guided radially movable, for example in the form of a cylindrical roller. The pump chamber is limited in the axial direction on the one hand by a suction plate and on the other hand by a pressure plate. In the radial direction, it is limited by an intermediate plate. The intermediate plate has a recess formed eccentrically to the axis of rotation of the pump rotor, on whose inner circumference the displacement elements can roll at least indirectly. According to the invention, a radially outer recess and a radially inner recess are formed in the pressure plate. Both recesses are in fluid communication with an outlet of the unit. Both recesses may have an example kidney-shaped contour. The two recesses are connected by a channel formed in the pressure plate, whereby a pressure equalization between the two recesses can be achieved across the channel during pumping.

Due to the possibility of being able to effect a volume flow between the two recesses via the channel formed in the pressure plate, a damped movement of the displacement elements within the radial grooves of the pump rotor can be effected both in the radial and in the axial direction. By means of an optimized flow of the fluid to be pumped through the unit, the displacement elements can thus be stabilized during pumping. It can come to a pressure equalization between the recesses above and below the displacement elements. In this way, a radial and / or axial housing acceleration can be reduced in the proposed unit, which in turn can lead to a quiet operation in a vehicle.

The formed between the radially outer and the radially inner recess in the pressure plate channel may be an elongated channel. A main extension axis of the channel, that is, its longitudinal axis, can be aligned from the radially inner recess to the radially outer recess substantially in the direction of rotation of the rotating pump rotor. "In the direction of rotation" is intended to mean that the main extension axis of the channel from the inner recess to the outer recess, for example, should be aligned approximately parallel or at a small angle obliquely to the rotating direction of rotation of the rotating pump rotor and this should at least not be directed opposite. In other words, the main extension axis of the elongated channel may be aligned from the radially inner recess to the radially outer recess at an acute angle to the inner periphery of the recess in the intermediate plate.

The fact that the channel extends substantially in the direction of rotation of the rotating pump rotor and preferably at an acute angle to the inner circumference of the recess, can be achieved that the roller-like displacement elements, which move during the pumping circular along the inner circumference of the recess without major mechanical Can move resistance across the channel. The risk that the displacement elements thereby encounter edges of the channel or even get caught with them, can be minimized due to such a favorable orientation of the channel. This can contribute to a further noise reduction. Alternatively, however, the channel can also be oriented radially or transversely.

A cross section of the channel may be tapered from the radially inner recess toward the radially outer recess. In other words, a cross section of the channel may be larger in the vicinity of the inner recess than in the vicinity of the outer recess. It has been observed that with such a design of the channel favorable flow conditions can be created within the delivery unit, which can contribute to noise minimization.

A bottom of the channel may be from the radially inner. Recess towards the radial. be formed rising outer recess. In other words, the depth of the channel formed in the pressure plate may be greater in the vicinity of the inner recess than in the vicinity of the outer recess. This too can have an advantageous effect on flow conditions and noise development to be minimized.

The channel may extend from a trailing in the direction of rotation of the pump rotor end of the radially inner recess toward a trailing in the direction of rotation of the pump rotor end of the radially outer recess. In other words, the channel can each connect the viewed in the direction of rotation of the pump rotor rear ends of the radially inner and the radially outer recess with each other. This too has proven to be advantageous for the flow conditions and the associated noise development.

It should be understood that aspects and features of the invention may be described herein with reference to various embodiments. One skilled in the art will recognize, however, that the features of the various embodiments may be combined as desired to arrive at other advantageous embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention are explained below with reference to the drawings.

1 shows a cross section through an aggregate for conveying fuel according to an embodiment of the present invention.

2 shows an exploded perspective view of components of a unit for conveying fuel according to an embodiment of the present invention.

3 shows a plan view of a suction plate of a unit for conveying fuel according to an embodiment of the present invention.

4 FIG. 12 illustrates an arrangement of a pump rotor with respect to inlet and outlet recesses for a fuel delivery unit in accordance with an embodiment of the present invention. FIG.

The figures are only schematic and not to scale. Identical or equivalent components are identified by the same reference numerals.

DESCRIPTION OF EMBODIMENTS OF THE INVENTION

1 shows an aggregate 100 for conveying fuel to an internal combustion engine 9 , The unit according to the invention has a cylindrical housing 1 with an input channel 2 and an output channel 3 , The input channel of the unit can be connected via a suction line 6 with a fuel tank 7 be connected. The output channel 3 of the unit can be via a pressure line 8th with the internal combustion engine 9 be connected. Such an aggregate is known for example as a so-called roller-cell pump or so-called vane pump. An example of a roller cell pump is in DE 101 15 866 A1 , the content of which is expressly intended to be part of the disclosure of this application.

The housing 1 of the aggregate 100 has a pump part 12 and a drive part 13 , The pump part 12 has a pump chamber 14 on, which may be cylindrical, for example. In the pump chamber 14 is a pump rotor 22 rotatably mounted, wherein the pump rotor 22 and the pump chamber 14 are arranged eccentrically to each other. The pump rotor 22 can have one in the drive part 13 provided drive motor 18 via a drive shaft 19 be driven in rotation.

The in the pump part 12 arranged components of the unit 100 will now be made with reference to the cross-sectional view 1 and the exploded perspective view 2 described.

The pump part 12 has one through the drive motor 18 circumferentially driven disk-shaped pump rotor 22 on that of the drive shaft 19 can be driven in rotation. The pump rotor 22 has several, for example, five, distributed over the circumference of radial grooves 26 arising from the circumference of the pump rotor 22 over part of the radial extent of the pump rotor 22 extend radially inward. In the grooves 26 is in each case a displacement element 28 arranged radially movable. As displacement elements 28 For example, rollers, balls or other rolling elements can be used.

The pump rotor 22 is in the pump chamber 14 arranged in the direction of the drive shaft 19 through a pressure plate 32 is limited. In the axial direction of the drive motor 18 away joins the pressure plate 32 an intermediate plate 34 on, which limits the pump chamber in the radial direction. The printing plate 32 has a hole 31 for the passage of the drive shaft 19 on. The intermediate plate 34 has an axial recess 36 up to the pressure plate 32 extends and which is formed in cross-section, for example, at least approximately circular. The recess 36 is eccentric to the axis of rotation of the drive shaft 19 of the pump rotor 22 arranged. The printing plate 32 and the intermediate plate 34 may be formed in one piece or as two separate components. The pump rotor 22 directed surface of the printing plate 32 is inside the recess 36 the intermediate plate 34 at least approximately flat.

During a rotary movement of the pump rotor 22 roll the displacement elements 28 on the inner circumference of the recess 36 from. It can be provided that between the inner circumference of the recess 36 and the pump rotor 22 a sliding ring is formed, which is formed of a material with good sliding properties. The shape of the inner circumference of the recess 36 For example, at least approximately may be a circle, but it may alternatively deviate from the circular shape. It can also coatings of wear-resistant material with favorable sliding properties on the inner circumference of the recess 36 be educated.

In the opposite axial direction, the pump rotor is adjacent 22 to a suction plate 40 on, which has at least an approximately flat surface on this page. In the suction plate 40 is a part of the circumference of the suction plate 40 extending kidney-shaped radially outer recess 42 and a radially inner recess 43 formed by the rotating pump rotor 22 Fuel is sucked into the pump. In the printing plate 32 are also a part of the circumference of the pressure plate 32 extending kidney-shaped radially outer recess 33 and a radially inner recess 35 formed by the pump part 12 subsidized fuel can escape. The recesses serving as suction opening 42 . 43 in the suction plate 40 and the recesses serving as a pressure opening 33 . 35 in the printing plate 32 are arranged offset from each other in the circumferential direction.

When operating the unit 100 the pump rotor is running 22 eccentric in the recess 36 the intermediate plate 34 around. The displacement elements 28 are driven by the force acting on these centrifugal force to the outside, so that they on the one raceway forming inner circumference of the recess 36 the intermediate plate 34 are pressed and due to the rotation of the pump rotor 22 unroll at this. This results between the peripheral surface of the pump rotor 22 and the inner periphery of the recess 36 crescent-shaped pump work spaces passing through the individual displacement elements 28 are delimited from each other and their volume during rotation of the pump rotor 22 from the intake opening, through the recesses 42 . 43 in the suction plate 40 are formed, in the direction of rotation towards the pressure opening through the recesses 33 . 35 in the printing plate 32 are reduced down. By the rotation of the pump rotor 22 the fuel in the pump work chambers is accelerated and by reducing the volume of the pump work chambers, an increase in pressure of the fuel takes place and this flows out through the pressure opening.

3 shows an intermediate housing 45 that is a combination of the pressure plate 32 and the intermediate plate 34 represents. The inner circumference of the intermediate plate 34 limited a recess 36 and forms a tread for the displacement elements 28 , The annular intermediate plate 34 protrudes from the pressure plate 32 in the direction of the pump rotor 22 from. 3 shows a plan view of the interior of the intermediate plate 45 , that is, on the surface, in the assembled state in contact with the pump rotor 22 comes.

In the printing plate 32 are two recesses 33 . 35 educated. A radially outer, kidney-shaped recess 33 is in fluid communication with a radially inner kidney-shaped recess 35 ,

According to the invention, the radially outer recess 33 and the radially inner recess 35 through a canal 50 connected with each other. Of the channel 50 is elongated and extends from one in the direction of rotation 51 seen trailing end of the radially inner recess 35 towards a direction of rotation 51 seen trailing end of the radially outer recess 33 , The channel 50 extends substantially in the direction of rotation 51 or at an acute angle to the inner circumference of the recess 36 ,

As can be seen in the sectional view AA, is a floor 52 of the canal 50 from the radially inner recess 35 towards the radially outer recess 33 formed rising so that forms a cross section of the channel 50 from the inner recess 35 towards the outer recess 33 rejuvenated. The width of the channel 50 can be constant, that is, the adjacent side walls of the channel 50 can be parallel. Alternatively, the side walls may also be arranged conically with respect to one another or be curved. The floor 52 the channel may be flat or, depending on the geometry of the channel width, be curved.

In 4 the operation of the pump section is again illustrated. On the one hand, the pump rotor 22 with the grooves formed therein 26 at its periphery and the displacement elements received therein 28 shown. In addition, the inner circumference of the recess is also 36 to which the displacement elements 28 can roll along, shown. In addition, the positions of the kidney-shaped recesses 33 and 35 in the printing plate 32 , which lead to a pressure outlet, as well as the positions of the kidney-shaped recesses 42 . 43 in the suction plate 40 that lead to an inlet side, shown schematically.

The during rotation in the direction of rotation 51 Successful movement of the roller-like displacement elements 28 is with respect to their direction and strength by arrows 53 illustrated with corresponding arrow direction and arrow thickness. Furthermore, this is in an active chamber 54 contained and compressed during rotation fluid is shown schematically.

During a rotation of the pump rotor 22 is to be compressed fluid from a suction side, in 4 on the left side, through the kidney-shaped recesses 42 . 43 in sickle-shaped areas between the pump rotor 22 and the outer periphery of the recess 36 sucked. The pump rotor 22 then continue to rotate clockwise. The displacement element 28 closes the sickle-shaped area tightly. On one of the suction side opposite outlet side, in 4 is due to the eccentric rotating pump rotor 22 compressed fluid then through the kidney-shaped recesses 33 . 35 pressed to the outlet.

During the pumping process, considerable forces can be exerted on the roller-shaped displacement elements 28 come. To the displacement elements 28 to stabilize, therefore, is the channel 50 between the radially inner recess 35 and the radially outer recess 33 provided at the pump outlet. This channel 50 can a volume flow with balancing effect and thus a damping of the movement of the displacement elements 28 effect in the radial as well as in the axial direction. This in turn can reduce or avoid an otherwise usually occurring disturbing noise during operation of the delivery unit.

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 10333190 A1 [0002]
• DE 10115866 A1 [0002, 0020]

Claims (7)

Aggregate ( 100 ) for conveying fuel with a drive motor ( 18 ) and a pump part ( 12 ), the pump part ( 12 ) one in a pump chamber ( 14 ), by the drive motor ( 18 ) rotatably driven pump rotor ( 22 ), distributed over its circumference a plurality of radial grooves ( 26 ), in each of which a displacement element ( 28 ) is guided radially movable, wherein the pump chamber ( 14 ) in the axial direction on the one hand by a suction plate ( 40 ) and on the other hand by a pressure plate ( 32 ) is limited and in the radial direction by an intermediate plate ( 34 ) is limited, wherein the intermediate plate ( 34 ) an eccentric to the axis of rotation ( 19 ) of the pump rotor ( 22 ) formed recess ( 36 ), on whose inner circumference the displacement elements ( 28 ) at least indirectly, characterized in that in the pressure plate ( 32 ) a radially outer recess ( 33 ) and a radially inner recess ( 35 ) which are in fluid communication with an outlet ( 3 ) of the unit and the one through the other in the pressure plate ( 32 ) trained channel ( 50 ) are connected. An assembly according to claim 1, wherein the channel ( 50 ) is elongated and a main axis of extension of the channel ( 50 ) of the radially inner recess ( 35 ) to the radially outer recess ( 33 ) essentially in the direction of rotation ( 51 ) of the rotating pump rotor ( 22 ) is aligned. An assembly according to claim 1 or 2, wherein the channel ( 50 ) is elongated and a main axis of extension of the channel ( 50 ) of the radially inner recess ( 35 ) to the radially outer recess ( 33 ) at an acute angle to the inner circumference of the recess ( 36 ) is aligned. Unit according to one of claims 1 to 3, wherein a cross-section of the channel ( 50 ) of the radially inner recess ( 35 ) towards the radially outer recess ( 33 ) rejuvenated. Aggregate according to one of claims 1 to 4, wherein a soil ( 52 ) of the channel ( 50 ) of the radially inner recess ( 35 ) towards the radially outer recess ( 33 ) is formed rising. An assembly according to any one of claims 1 to 5, wherein the channel ( 50 ) from one in the direction of rotation ( 51 ) trailing end of the radially inner recess ( 35 ) to a trailing in the direction of rotation end of the radially outer recess ( 33 ). Unit according to one of claims 1 to 6, wherein the radially inner recess / 35 ) and / or the radially outer recess ( 35 ) are kidney-shaped.

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