DE102009049468A1 - Casted unbalanced shaft for balancing mass-force/mass-torque of reciprocating piston-internal combustion engine in four cylinder-series construction, has rings whose casing surface is supported at circumference points of bearing section - Google Patents

Abstract

The shaft (1') has bearing sections (13') axially limiting unbalanced sections (10, 11), and bearing rings (21') mounted on the bearing sections in a fixed manner. Outer casing surface of the bearing rings serves as a rolling-or sliding bearing track for a roller bearing i.e. needle sleeve, or sliding bearing. An inner casing surface (22) of the bearing rings is supported in a longitudinal sectional level at diametrical opposite lying circumference points (24, 25) of the bearing sections, where the level is stretched by a rotation axis (19) and balance direction of the shaft.

Description

Field of the invention

The invention relates to an imbalance shaft with an unbalanced portion, an axially adjacent thereto bearing portion and a fixedly mounted on the bearing portion bearing ring whose cylindrical outer surface serves as a rolling or sliding bearing raceway for an unbalanced shaft bearing Wälz or sliding bearing, wherein the bearing portion of a straight Circular cylinder deviating shape has such that the center of gravity of the bearing portion is offset in the unbalance direction of the imbalance shaft eccentric to its axis of rotation. The imbalance shaft is used in particular to compensate for inertial forces and / or mass moments of an internal combustion engine.

Background of the invention

Generic imbalance waves go out of the DE 10 2007 009 800 A1 and the not pre-published DE 10 2009 035 112 A1 out. A significant mass reduction of the imbalance shaft is achieved in each case that not only the imbalance sections but also the bearing sections are involved in the generation of the wave imbalance. The bearing sections have for this purpose a deviating from a straight circular cylinder shape, namely the shape of a cylinder segment having a cross-sectional area which is substantially mirror-symmetrical to the co-rotating unbalance direction and whose center of gravity is eccentric to the axis of rotation in unbalance direction. In contrast, the straight circular cylinder is known to be a geometric body having a circular cross-section in each cross-sectional plane.

On the respective arcuate outer circumferential surface of the cylinder segments, a bearing ring is fixedly mounted, for example by means of a press fit to a closed, d. H. 360 ° amount of career of a sliding bearing or for the rolling elements of a rolling bearing to form the radial bearing of the imbalance shaft in the internal combustion engine. The bearing ring is cantilevered at the circumferential location which is diametrically opposed to the unbalance direction.

Object of the invention

The present invention has for its object to improve an imbalance shaft of the type mentioned in terms of the structural design of the bearing.

Summary of the invention

According to the invention this object is achieved by the characterizing features of claim 1, while advantageous developments and refinements of the subclaims can be removed. Accordingly, the inner circumferential surface of the bearing ring in a longitudinal sectional plane which is spanned by the axis of rotation and the unbalance direction of the imbalance shaft to be supported at diametrically opposite circumferential locations of the bearing portion. In other words, in contrast to the prior art cited above, it is intended to support the bearing ring diametrically opposite the co-rotating unbalance direction on the bearing section even in the slightly or not loaded circumferential region. This is especially advantageous for the fatigue strength of a preferably provided longitudinal or transverse compression bandage between bearing ring and bearing section.

While the closed bearing ring is as thin as possible in view of the low mass of the unbalanced shaft and in the case of rolling bearing suitably consists of a bearing steel such as 100Cr6, the imbalance shaft can otherwise be designed as economically producible cast shaft without special load capacity for a rolling contact and in particular as a steel casting.

In a first alternative embodiment of the invention, the bearing section should have a circular cross-section in a cross-sectional plane that is perpendicular to the axis of rotation of the imbalance shaft and within the width of the bearing ring. This means that the inner lateral surface of the bearing ring is axially only partially, but fully supported in favor of a further stabilized press fit on the bearing portion.

Here, a favorable mass distribution of the bearing section - d. H. its center of mass is eccentric as far as possible in unbalance direction - resulting in that the bearing portion has a variable width over its circumference in the direction of the axis of rotation, wherein the width of the bearing portion at its pointing in the unbalance circumferential location is significantly greater than at its diametrically opposite circumferential point.

In a second alternative embodiment of the invention, the bearing section in a cross-sectional plane which is perpendicular to the axis of rotation of the imbalance shaft and within the width of the bearing ring, to have a deviating from the circular cross-section. This means that the inner circumferential surface of the bearing ring in this case is only partially supported on the bearing portion.

A particularly favorable mass distribution of such a bearing section can now result from the fact that the bearing section has a substantially E-shaped and mirror-symmetrical to the longitudinal section plane cross-section.

In the case of roller bearings, the bearing ring should be radially penetrated at a cantilevered circumferential location of at least one and preferably a plurality of openings arranged offset over the circumference and / or in the direction of the axis of rotation on the roller bearing raceway and serve to supply lubricant to the rolling bearing.

Such lubricant openings, which can be produced, for example, by punching the bearing ring, provide a freely flow-through connection between the oil mist filled environment of the bearing portion and the raceway of the bearing ring in order to provide the rolling rolling elements and the raceway can be supplied in sufficient quantity with non-pressurized lubricant. The lubricant openings are advantageous in the low or not at all loaded peripheral region of the bearing ring, d. H. opposite to the unbalance direction facing load zone to position. Thus, the track is free of interruptions in the region of the co-rotating load zone on the part of the center of gravity and in this respect has a maximum bearing capacity for the rolling contact.

Brief description of the drawings

Further features of the invention will become apparent from the following description and from the drawings, in which embodiments of unbalanced shafts according to the invention are shown partially simplified. Unless otherwise stated, the same or functionally identical features or components are provided with the same reference numbers. Show it:

1 the bearing point of a first imbalance shaft in two views;

2 the bearing point of a second imbalance shaft in two views;

3 a well-known imbalance wave in perspective and

4 a known device for mass balance of an internal combustion engine in a schematic representation.

Detailed description of the drawings

The invention is based on the 3 and 4 explained in more detail, in which a known imbalance wave 1 disclosed, which is used to compensate for second-order inertial forces of a reciprocating internal combustion engine in four-cylinder in-line construction. Such as Lancaster compensation known mass balance gear goes out of the in 4 shown transmission scheme. The internal combustion engine 2 includes four in cylinders 3 oscillating pistons 4 whose longitudinal movement is via connecting rods 5 in the rotation of the crankshaft 6 is implemented. This drives - here on an intermediate wave 7 - two imbalance waves 1 with imbalances 8th on, with the imbalance waves 1 parallel to the crankshaft 6 Rotate in opposite directions with double crankshaft speed.

Every imbalance wave 1 connected to a drive section 9 is driven for example via a sprocket or gear, not shown, comprises three imbalance sections 10 . 11 and 12 and two axially adjacent thereto bearing sections 13 where the imbalance wave 1 in not shown housing bearing points of the internal combustion engine 2 are radially mounted roller bearings. As rolling bearings come needle sleeves 14 used, each from a cage 15 with needles in it 16 as rolling elements and a non-cutting, thin-walled outer ring 17 consist. The outer circumferential surfaces 18 the bearing sections 13 serve as a track for the needles 16 , and the imbalance wave 1 is manufactured in view of the heavily loaded rolling contact as a steel forging.

In favor of the lowest possible wave mass, both the imbalance sections 10 . 11 and 12 as well as the bearing sections 13 Mass centers on which to generate the wave imbalance eccentric to the axis of rotation 19 and run in a common unbalance level. As it is the radial bearing of the imbalance shaft 1 As is known, a circulation ratio with point load on the bearing sections 13 and circumferential load on the housing bearing points of the internal combustion engine 2 acts, forms on the outer shell surfaces 18 the bearing sections 13 a stationary load zone, with respect to the center of gravity on this side of the axis of rotation 19 and symmetrical to the unbalance plane. In contrast, the diametrically opposite partial circumference of the bearing sections 13 essentially load-free.

The point load of the bearing sections 13 allows it, the outer circumferential surfaces 18 with a circumferentially variable width in the direction of the axis of rotation 19 to design. As it is from the in 3 left illustrated bearing section 13 with cut open needle sleeve 14 becomes clear, is the width of the bearing sections 13 at their pointing in the unbalance direction circumferential point significantly larger than at the diametrically opposite circumferential point, at which the outer circumferential surface 18 a possibly low bearing load is exposed. The direction of unbalance is indicated by the arrow 20 symbolizes.

In the following with reference to the 1 and 2 explained embodiments of inventive unbalanced shafts 1' and 1'' , which are manufactured as comparatively inexpensive cast steel shafts without requirements for a rolling bearing raceway, are the bearing sections 13 ' respectively. 13 '' with bearing rings 21 ' respectively. 21 '' provided, the cylindrical outer circumferential surfaces 18 serve as a tribologically highly resilient roller bearing raceway. The bearing rings 21 ' . 21 '' are each by means of a transverse compression bandage, in which for mounting the bearing ring 21 ' . 21 '' heated and / or the imbalance shaft 1' . 1'' is cooled, on the associated bearing section 13 ' . 13 '' assembled. A stabilized permanent attachment of the bearing rings 21 ' . 21 '' is achieved according to the invention in that the inner circumferential surface 22 the bearing rings 21 ' . 21 '' in a longitudinal section plane 23 passing through the axis of rotation 19 and the unbalance direction 20 the imbalance waves 1' . 1'' is clamped, at diametrically opposite circumferential locations 24 and 25 the bearing sections 13 ' . 13 '' is supported.

According to the in 3 illustrated imbalance wave 1 have the bearing sections 13 ' . 13 '' one of a straight circular cylinder deviating shape with a in the unbalance direction 20 eccentric to the axis of rotation 19 shifted mass center of gravity 26 so not only in the details according to the 1a , Federation 2a , unbalance sections shown b 10 and 11 but also the bearing sections 13 ' . 13 '' contribute to the generation of the wave imbalance.

The 1a and 1b show the bearing of the imbalance shaft 1' with storage section 13 ' and attached bearing ring 21 ' , The design of the bearing section 13 ' is basically the same as in 3 illustrated bearing section 13 with circumferentially variable width in the direction of the axis of rotation 19 , Geometrically, therefore, has the bearing section 13 ' in a cross-sectional plane 27 perpendicular to the axis of rotation 19 and within the circumferential constant width of the bearing ring 21 ' runs, a circular cross-section, so that the inner circumferential surface 22 of the bearing ring 21 ' axially only partially, but fully on the bearing section 13 ' is supported.

The lubricant supply of the rolling bearing raceway 18 and the rolling elements (needles 16 according to 3 ) via openings 28 that the bearing ring 21 ' penetrate radially. A total of six punched openings are planned 28 at cantilevered points of the bearing ring 21 ' run and over the low-load part circumference and - with respect to the cross-sectional plane 27 - in the direction of the axis of rotation 19 offset, so are arranged in two rows. About the openings 28 becomes operational lubricant mist with the assistance of centrifugal acceleration due to rotation of the imbalance shaft 1' from the environment of the storage section 13 ' transported to the rolling contacts.

The 2a and 2 B show the bearing of the imbalance shaft 1'' with storage section 13 '' and attached bearing ring 21 '' , In this embodiment, the bearing section 13 '' in the cross-sectional plane 27 a deviating from the circular cross section, the substantially E-shaped and the longitudinal sectional plane 23 is mirror-symmetrical. The E-shaped cross section results from three opposite to the unbalance direction 20 extending ribs 29 . 30 and 31 , where the middle rib 30 the width of the bearing ring 21 '' has and the outer ribs 29 and 31 against the unbalance direction 20 to rejuvenate in width. The open spaces between the ribs 29 . 30 and 31 cause the inner circumferential surface 22 of the bearing ring 21 '' only part of the circumference, namely at the circumferential location 25 just on the rib 30 on the storage section 13 '' is supported.

The lubricant supply of the rolling bearing raceway 18 and the rolling elements (needles 16 according to 3 ) takes place in this case via four circumferentially offset openings 28 that the bearing ring 21 '' axially in the middle, that is to say in a single-row radial pass.

LIST OF REFERENCE NUMBERS

1

unbalanced shaft

2

Internal combustion engine

3

cylinder

4

piston

5

pleuel

6

crankshaft

7

intermediate shaft

8th

unbalance

9

driving section

10

unbalanced section

11

unbalanced section

12

unbalanced section

13

bearing section

14

Rolling bearings / needle roller bearing

15

Cage

16

Needle / rolling elements

17

outer ring

18

Outer surface area / career

19

Rotary axis of the imbalance shaft

20

unbalance direction

21

bearing ring

22

Inner lateral surface of the bearing ring

23

Longitudinal section plane

24

peripheral location

25

peripheral location

26

Center of gravity

27

Cross-sectional plane

28

lubricant opening

29

rib

30

rib

31

rib

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 102007009800 A1 [0002]
• DE 102009035112 A1 [0002]

Claims (8)

Imbalance shaft ( 1' . 1'' ), in particular for balancing mass forces and / or mass moments of an internal combustion engine ( 2 ), with an imbalance section ( 10 . 11 . 12 ), an axially adjacent thereto bearing section ( 13 ' . 13 '' ) and one on the storage section ( 13 ' . 13 '' ) permanently mounted bearing ring ( 21 ' . 21 '' ), whose cylindrical outer circumferential surface ( 18 ) as a rolling or plain bearing raceway for an imbalance shaft ( 1' . 1'' ) rolling bearing ( 14 ) or sliding bearing, wherein the bearing section ( 13 ' . 13 '' ) has a shape deviating from a right circular cylinder such that the center of mass ( 26 ) of the storage section ( 13 ' . 13 '' ) in unbalance direction ( 20 ) of the imbalance shaft ( 1' . 1'' ) eccentric to its axis of rotation ( 19 ), characterized in that the inner circumferential surface ( 22 ) of the bearing ring ( 21 ' . 21 '' ) in a longitudinal section plane ( 23 ) passing through the axis of rotation ( 19 ) and the unbalance direction ( 20 ) of the imbalance shaft ( 1' . 1'' ) is clamped at diametrically opposite circumferential locations ( 24 . 25 ) of the storage section ( 13 ' . 13 '' ) is supported. Imbalance shaft ( 1' . 1'' ) according to claim 1, characterized in that it is a cast imbalance shaft. Imbalance shaft ( 1' ) according to claim 1, characterized in that the bearing section ( 13 ' ) in a cross-sectional plane ( 27 ) perpendicular to the axis of rotation ( 19 ) of the imbalance shaft ( 1' ) and within the width of the bearing ring ( 21 ' ), has a circular cross-section, wherein the inner circumferential surface ( 22 ) of the bearing ring ( 21 ' ) axially only partially, but fully on the bearing section ( 13 ' ) is supported. Imbalance shaft ( 1' ) according to claim 3, characterized in that the bearing section ( 13 ' ) a variable over its circumference width in the direction of the axis of rotation ( 19 ), wherein the width of the bearing section ( 13 ' ) at which in the unbalance direction ( 20 ) pointing circumferential location ( 24 ) significantly larger than at its diametrically opposite circumferential point ( 25 ). Imbalance shaft ( 1'' ) according to claim 1, characterized in that the bearing section ( 13 '' ) in a cross-sectional plane ( 27 ) perpendicular to the axis of rotation ( 19 ) of the imbalance shaft ( 1'' ) and within the width of the bearing ring ( 21 '' ), has a different cross-section from the circular shape, so that the inner circumferential surface ( 22 ) of the bearing ring ( 21 '' ) only partly on the bearing section ( 13 '' ) is supported. Imbalance shaft ( 1'' ) according to claim 5, characterized in that the bearing section ( 13 '' ) a substantially E-shaped and the longitudinal section plane ( 23 ) has mirror-symmetrical cross-section. Imbalance shaft ( 1' . 1'' ) according to claim 1, characterized in that the bearing ring ( 21 ' . 21 '' ) at a cantilevered circumferential location of at least one on the rolling bearing raceway ( 18 ) leaking opening ( 28 ) for supplying lubricant to the rolling bearing ( 14 ) is penetrated radially. Imbalance shaft ( 1' . 1'' ) according to claim 7, characterized in that the bearing ring ( 21 ' . 21 '' ) of several over the circumference and / or in the direction of the axis of rotation ( 19 ) offset lubricant openings ( 28 ) is interspersed.

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