EP4176164A1 - Sliding bearing with a lubricant channel and with at least three axial slide positions - Google Patents

Abstract

The invention relates to a sliding bearing comprising a bearing housing (29) and a bearing piece mounted rotatably and axially moveabley within a bearing opening (30) of the bearing housing (29), in particular in the form of a cam piece (27), which forms an outer bearing surface (33), which contacts an inner bearing surface (32) of the bearing housing (29) forming a contact gap (34), wherein a first lubricant channel (35) and a second lubricant channel (36) are integrated into the bearing housing (29) or into the bearing piece to supply lubricant to the contact gap (34), and they are spaced apart from one another and feed into the inner bearing surface (32) or the outer bearing surface (33) and wherein a supply of lubricant via the first lubricant channel (35) and the second lubricant channel (36) can be influenced by a distribution device. The the ability of the bearing piece to move axially relative to the bearing housing (29) is such that the outer bearing surface (33) or the inner bearing surface (22) covers the feed openings (38) of the first lubricant channel (35) and the second lubricant channel (36) in a first slide position of the sliding bearing, and covers the feed opening (38) of the first lubricant channel (35) and releases the feed opening (38) of the second lubricant channel (36) in a second slide position of the sliding bearing, and releases the feed opening (38) of the first lubricant channel (35) and covers the feed opening (38) of the second lubricant channel (36) in a third slide position of the sliding bearing.

Description

description

Plain bearings with a lubricant channel and at least three axial slide positions

The invention relates to a slide bearing that can be used in particular in a valve train of an internal combustion engine, a bearing piece of the slide bearing, which can be designed in particular as a cam piece of the valve train, is rotatably and axially displaceably mounted within a bearing opening of a bearing housing. The axial displaceability is used, if necessary, to bring different cam elevations of the cam piece into operative connection with a gas exchange valve of the internal combustion engine, whereby the actuation of the gas exchange valve is changed during operation of the internal combustion engine. In order to minimize the friction between the bearing housing and the bearing piece, a lubricant channel is integrated into the bearing housing, via which lubricant can be fed to the contact gap formed between the bearing housing and the bearing piece.

A corresponding valve drive is known from DE 102017203869 A1. In this valve drive, the cam piece can be positioned in two axial sliding positions relative to the bearing housing that receives it. The lubricant channel formed in the bearing housing runs radially and, with respect to the axial extent (along the axis of rotation), is arranged centrally in the inner bearing surface of the bearing housing provided for contact with the cam piece.

A similar valve drive is also known from DE 102017205463 A1, with this valve drive lubricant channels which are integrated into the cam piece for a supply of lubricant to the contact gap of a plain bearing, which is formed by a cam piece and a bearing housing.

A valve drive in which cam pieces of a camshaft that can be shifted in three stages are mounted in plain bearings and in which the radius of the outer bearing surfaces of the cam pieces is greater than the largest radius of three different cam lobes is known from DE 102017210661 A1.

The invention was based on the object of specifying a slide bearing which is advantageously suitable for a rotatable and at least three-stage axially displaceable mounting of a cam piece in a bearing housing of a valve drive of an internal combustion engine. This object is achieved in a slide bearing according to claim 1. A valve train with such a plain bearing and an internal combustion engine with a corresponding valve train are the subject matter of claims 9 and 11. Advantageous embodiments of the slide bearing, valve train and internal combustion engine are the subjects of the further claims and / or result from the following description of the invention.

According to the invention, a plain bearing is provided which has at least one bearing housing and a bearing piece that is rotatably and axially displaceably mounted (each with respect to a relative axis of rotation) within a bearing opening of the bearing housing, the bearing piece forming an outer bearing surface that forms an inner bearing surface of the bearing housing with the formation of a Contact gap contacted. In the bearing housing or the bearing piece, a first lubricant channel and a second lubricant channel are integrated, which are provided for a supply of lubricant to the contact gap, these lubricant channels axially spaced from each other open into the inner bearing surface of the bearing housing or in the outer bearing surface of the bearing piece and whereby by means of a Distribution device a supply of lubricant via the first lubricant channel and the second lubricant channel can be influenced.

The axial displaceability of the bearing piece relative to the bearing housing is provided according to the invention in such a way that the outer bearing surface of the bearing piece or the inner bearing surface of the bearing housing in a first sliding position covers the mouth openings of the first lubricant channel and the second lubricant channel (at least largely, preferably completely). In this first sliding position, the distribution device preferably brings about a supply of lubricant to the contact gap both via the first lubricant channel and the second lubricant channel.

In a second sliding position, the outer bearing surface of the bearing piece or the inner bearing surface of the bearing housing covers the mouth opening of the first lubricant channel (at least largely, preferably completely) and releases the mouth opening of the second lubricant duct (at least largely, preferably completely) (i.e. at least covers the mouth opening of the second lubricant channel mostly not). In this second sliding position, the distribution device preferably brings about a supply of lubricant to the contact gap exclusively via the first lubricant channel (i.e. not also via the second lubricant channel).

In a third sliding position, the outer bearing surface of the bearing piece or the inner bearing surface of the bearing housing form the mouth of the first lubricant channel (at least for the most part, preferably completely) free and covers (at least for the most part, preferably completely) the mouth opening of the second lubricant channel. In this third sliding position, the distribution device preferably brings about a supply of lubricant to the contact gap exclusively via the second lubricant channel (ie not also via the first lubricant channel).

Such a plain bearing enables an advantageous supply of lubricant to the contact gap in the at least three sliding positions, which also applies in particular when, as is preferably provided, the outer bearing surface of the bearing piece and the inner bearing surface in the second sliding position and / or in the third sliding position of the bearing ring only partially overlap. This makes it possible to design both the outer bearing surface of the bearing piece and the inner bearing surface of the bearing housing with a relatively small extension in the axial direction (with respect to the relative axis of rotation), whereby the space requirement for the integration of such a plain bearing in, for example, a valve drive according to the invention for an internal combustion engine is relatively small .

Such a valve drive comprises at least one camshaft which is mounted in a sliding bearing according to the invention, the camshaft being designed as a cam piece or comprising at least one such cam piece and this cam piece being the bearing piece of the sliding bearing. Furthermore, the valve drive comprises at least three cam elevations arranged axially offset from one another, at least two, preferably all three, cam elevations differing. These cam elevations can alternatively be brought into operative connection by a corresponding axial displacement of the cam piece with a gas exchange valve of an internal combustion engine according to the invention, whereby these actuate the gas exchange valve with different valve lift profiles. The gas exchange valve is assigned to a combustion chamber of the internal combustion engine in order to control the introduction of fresh gas into this combustion chamber or the removal of exhaust gas from this combustion chamber. An internal combustion engine according to the invention also includes an adjusting device for moving the cam piece.

According to a preferred embodiment of a valve drive according to the invention, it can be provided that the cam piece is designed in the form of a sleeve and is mounted on a base shaft of the camshaft in a rotationally fixed and axially displaceable manner. This avoids having to move the entire camshaft axially in order to bring the cam lobes alternately into operative connection with the gas exchange valve. The distribution device of a plain bearing according to the invention can preferably be designed in such a way that a preferably spherical valve body is arranged in each of the lubricant channels, which closes the respective lubricant channel and thereby prevents lubricant from being discharged from this lubricant channel if the associated mouth opening is not covered or released and consequently the mouth opening is arranged outside the contact gap. On the other hand, the valve body opens the respective lubricant channel and thereby enables lubricant to be supplied to the contact gap via this lubricant channel when the associated mouth opening is covered. As a result, it can be realized in a structurally particularly simple manner that lubricant only emerges from the respective mouth opening when it is also located in the area of the contact gap as a result of an overlap.

Particularly preferably, it can then be provided that the valve body, when it closes the associated lubricant channel, protrudes from the mouth opening of this lubricant channel. As a result, an automatic opening and closing of the lubricant channels as a result of an axial displacement of the bearing piece relative to the bearing housing can be achieved in that a valve body, which protrudes from the associated mouth opening if there is no overlap, is pressed into the associated lubricant channel when by a relative displacement the overlap of this mouth opening is realized between the bearing housing and the bearing piece.

In addition to these passive configurations of the adjustment device, other configuration options can also be considered, which can in particular also be configured actively, such as the integration of an actively controllable switching valve, by means of which lubricant can be directed into the first lubricant channel and / or the second lubricant channel as required.

According to a preferred embodiment of a plain bearing according to the invention, it can be provided that the first lubricant channel and the second lubricant channel are integrally formed in at least one section and thus, for example, only split into separate lubricant channels shortly before the orifice openings. As a result, the lubricant channels can be integrated into the bearing housing or the bearing piece in a relatively simple manner.

In an embodiment of a sliding bearing according to the invention, in which the bearing piece as a cam piece has at least three axially offset cam elevations, it can furthermore preferably be provided that the radius of the outer bearing surface of the bearing piece is larger than the largest radius of the cam lobes. This enables an advantageous assembly of such a plain bearing and in particular of a valve drive of an internal combustion engine comprising such a plain bearing. In addition, this can result in a particularly compact design of the sliding bearing with regard to the extension in the axial direction, in particular in combination with the likewise preferred embodiment, according to which the outer bearing surface of the bearing piece and the inner bearing surface of the bearing housing are in the second sliding position and / or in the third sliding position only partially cover it. The inner bearing surface of the bearing housing can then project beyond the outer bearing surface of the bearing piece or of the cam piece in the axial direction without a collision with a cam lobe which is preferably arranged axially adjacent to the outer bearing surface. Accordingly, it can also be provided that in the second and / or third sliding position at least one cam elevation is arranged at least partially within the bearing opening.

The invention is explained in more detail below with reference to an exemplary embodiment shown in the drawings. The drawings show, each in a simplified representation:

1: an internal combustion engine with an internal combustion engine according to the invention in a plan view;

2: the internal combustion engine in a longitudinal section;

3 shows a section of the valve drive of the internal combustion engine in a first sliding position of the associated cam piece;

4: the section of the valve drive in a second sliding position of the cam piece; and

5: the section of the valve drive in a third sliding position of the cam piece.

In Fig. 1, an internal combustion engine is shown. A motor vehicle (not shown), for example, can be driven by means of the internal combustion engine.

The internal combustion engine comprises the internal combustion engine 1 also shown in further detail in FIG. 2. The internal combustion engine 1 forms several (here: four) cylinder openings 4 in a combination of cylinder crankcase 2 and cylinder head housing 3. The cylinder openings 4 are connected on the inlet side to an intake pipe 5 of a fresh gas line 6 and on the outlet side to an exhaust manifold 7 of an exhaust line 8 of the internal combustion engine in a gas-carrying manner. In a known manner, in combustion chambers 9, which of the Cylinder openings 4 together with the piston 10 guided therein and the cylinder head housing 3 are limited, fresh gas (essentially air) burned with fuel. For this purpose, the fuel can be injected directly into the combustion chambers 9 by means of fuel injectors 11. The exhaust gas resulting from the combustion of the fuel-fresh gas mixture is discharged via the exhaust line 8.

The supply of fresh gas into the combustion chambers 9 and the discharge of the exhaust gas from the combustion chambers 9 is controlled via four gas exchange valves 12, 13, namely two inlet valves 12 and two outlet valves 13, for each combustion chamber 9, which are controlled by a valve drive not shown in FIG. 1 of the internal combustion engine 1 are operated. According to FIG. 2, the valve drive comprises a crankshaft 14 which forms crank pins 15, the crank pins 15 being connected to the pistons 10 via connecting rods 16. As a result, linear movements of the pistons 10 are converted into a rotation of the crankshaft 14, the rotation of the crankshaft 14 in turn causing a periodic change in direction of the linear movements of the pistons 10. The rotation of the crankshaft 14 is also transmitted via a control gear, for example a toothed belt gear 17, to two camshafts 18, each of which actuates two gas exchange valves 12, 13 per combustion chamber 9 via, for example, rocker arms or rocker arms (not shown).

The internal combustion engine also includes an exhaust gas turbocharger. This has an exhaust gas turbine 19 integrated into the exhaust gas line 8 and a fresh gas compressor 20 integrated into the fresh gas line 6. An impeller of the exhaust gas turbine 19 that is driven to rotate by the exhaust gas flow drives an impeller of the compressor 20 via a shaft 21. The rotation of the impeller of the compressor 20 brought about in this way compresses the fresh gas passed through it.

A charge pressure limitation can be achieved by means of a wastegate 22 in that part of the exhaust gas flow is guided past the exhaust gas turbine 19 when the internal combustion engine 1 is operating at high speed and / or load. Furthermore, an exhaust gas aftertreatment device 23 is integrated into the exhaust line 8.

The internal combustion engine also comprises an adjusting device 24, by means of which one of a total of three cam lobes 25 can be assigned to the inlet valves 12 and / or the outlet valves 13, if necessary. This adjusting device 24 can be controlled by a control device 26 and is only indicated schematically in FIG. 2. The function of the adjustment device 24 is based on the longitudinal axial displaceability of sleeve-shaped cam pieces 27, which are arranged in a rotationally fixed manner on a base shaft 28 via interlocking longitudinal teeth, the cam pieces 64 being the three different ones for each of the inlet valves 28 or outlet valves 30 that can be actuated by them Have cam elevations 25, which are alternatively brought into operative connection with the associated gas exchange valves 12, 13 as a function of the respectively set axial sliding position of the cam pieces 27. The structure and the mode of operation of the adjusting device 24 can correspond to those disclosed in DE 102017203869 A1, DE 102017205463 A1 and DE 102017210661 A1.

In addition to the base shaft 28 of the camshaft 18, the cam pieces 27 are each rotatably mounted in at least one slide bearing, this mounting of the cam pieces 27 also ensuring axial mobility, which enables the various sliding positions of the cam pieces 27, in which the various cam lobes 25 with the respective associated gas exchange valve 12, 13 are brought into working connection to adjust.

The slide bearings provided for mounting the cam pieces 27 include, according to FIGS.

3 to 5 each have a section of the cylinder head housing 3 as a bearing housing 29, which forms a cylindrical bearing opening 30 in which a cylindrical bearing section 31 of the respective cam piece 27 is arranged. The outer diameter of the bearing section 31 of the cam piece 27 is only slightly smaller than the inner diameter of the bearing opening 30 in order to achieve a largely play-free but also jam-free relative mobility between the bearing housing 29 and the bearing section 31 of the cam piece 27. The wall of the bearing housing 29 delimiting the bearing opening 30 represents an inner bearing surface 32 of the bearing housing 29 and the outer surface of the bearing section 31 of the cam piece 27 represents an outer bearing surface 33 of the cam piece 27, with a contact gap 34 between the overlapping area of the inner bearing surface 32 and the outer bearing surface 33 is trained.

For each of the slide bearings provided for mounting a cam piece 27, two lubricant channels 35, 36 are integrated into the cylinder head housing 3 and thus into the bearing housing 29 and are connected to a common lubricant source (not shown). The lubricant channels 35, 36 of each slide bearing are initially formed integrally, ie as a common channel section, and then separate into partial strands that are axially spaced apart (with respect to the axis of rotation 37 of the camshaft 18 and thus also the cam pieces 27) in the inner bearing surface 32 of the respective Bearing housing 29 open. By means of the lubricant channels 35, 36, a preferably liquid lubricant can be introduced into the contact gap 34 of each slide bearing in order to achieve a relative movement with as little friction as possible between the components of the slide bearing, ie between the cam pieces 27 and the cylinder head housing 3 of the internal combustion engine 1. 3 to 5 show different sliding positions of a sliding bearing of the internal combustion engine 1, which is provided for mounting a cam piece 27, wherein in a first sliding position according to FIG. 3 the bearing section 31 of the cam piece 27 is axially centered within the bearing opening 30 of the bearing housing 29 is positioned. The outer bearing surface 33 of the cam piece 27 (completely) covers the mouth openings 38 of both lubricant channels 35, 36, so that the contact gap 34 is also arranged in the area of both mouth openings 38. In this first sliding position, lubricant is fed to the contact gap 34 via both lubricant channels 35, 36. This is ensured by a corresponding functional position of a distribution device of the sliding bearing, which is formed by a spherical valve body 39 arranged within each of the lubricant channels 35, 36 and an associated valve seat 40 arranged in the area of the respective mouth opening 38.

If the outer bearing surface 33 of the cam piece 27 covers the mouth opening 38 of a lubricant channel 35, 36, the valve body 39 arranged in this lubricant channel 35, 36 is raised a little from the associated valve seat 40. This lubricant channel 35, 36 is thus opened, so that lubricant can flow into the contact gap 34 of the sliding bearing via the corresponding mouth opening 38. If, on the other hand, the outer bearing surface 33 of the cam piece 37 does not cover the mouth opening 38 of a lubricant channel 35, 36 or releases it, the valve body 39 arranged in this lubricant channel 35, 36 is counteracted at least by the pressure of the lubricant, possibly also by the force of gravity acting on it the associated valve seat 40 is pressed, whereby the corresponding lubricant channel 35, 36 is closed. In such a position of the valve body 39 pressed against the associated valve seat 40, it protrudes from the associated mouth opening 38 to such an extent that it is lifted off the valve seat by subsequent contact with the bearing section 31 of the cam piece 27 in order to open the corresponding lubricant channel 35, 36 .

In the first sliding position of a slide bearing provided for mounting a cam piece 27, a centrally arranged cam lobe 25 of the cam piece 27 is in operative connection with the associated gas exchange valve 12, 13 of the internal combustion engine 1.

4 shows a second sliding position of a sliding bearing provided for mounting a cam piece 27, in which the outer bearing surface 33 of the cam piece 27 covers the mouth opening 38 of a first (35) of the lubricant channels 35, 36 and exposes the mouth opening of the second lubricant channel 36. Lubricant is consequently only supplied to the contact gap 34 via the first lubricant channel 35. This prevents that lubricant exits via the second lubricant channel 36, whereby otherwise the lubricant would escape uncontrolled into the valve drive and not into the contact gap 34, which is not arranged in the area of the mouth opening 38 of the second lubricant channel 36 in the second sliding position. In the second sliding position, a cam lobe 25, arranged on the right in FIGS. 3 to 5, of the cam piece 27 is in operative connection with the associated gas exchange valve 12, 13 of the internal combustion engine 1.

5 shows a third sliding position of a sliding bearing provided for mounting a cam piece 27, in which the outer bearing surface 33 of the cam piece 27 covers the mouth opening 38 of the second lubricant channel 36 and exposes the mouth opening 38 of the first lubricant channel 35. Lubricant is then consequently only supplied to the contact gap 34 via the second lubricant channel 36. In the third sliding position, a cam lobe 25 arranged on the left in FIGS. 3 and 5 is in communication with the associated gas exchange valve 12, 13 of the internal combustion engine 1.

Both in the second sliding position according to FIG. 4 and in the third sliding position according to FIG 27 and only partially cover the inner bearing surface 32 of the bearing housing 29. This is a consequence of the relatively small dimensioning of the bearing housing 29 or the bearing opening 30 in the axial direction, which has an advantageous effect with regard to the space required for the sliding bearing when it is integrated into the internal combustion engine 1 and, in particular, with regard to the minimum distance between adjacent cylinder openings 4. This also means that in the second sliding position according to FIG. 4, a section of one of the cam elevations 25 is arranged within the bearing opening 30 of the sliding bearing.

In FIGS. 3 to 5 it can also be seen that the radius of the cylindrical outer bearing surface 33 of the cam piece 27 is larger than the largest radius of the cam lobes 25, which enables an advantageous assembly of the valve drive of the internal combustion engine 1, since the respective, preferably one-piece Cam piece 27 can be inserted into the associated bearing opening 30 in a simple manner. LIST OF REFERENCE NUMERALS Combustion engine Cylinder crankcase Cylinder head housing Cylinder opening Suction pipe Fresh gas line Exhaust manifold Exhaust line Combustion chamber Piston Fuel injector Gas exchange valve / inlet valve Gas exchange valve / outlet valve Crankshaft Crank pin Connecting rod Toothed belt drive Camshaft Exhaust gas turbine Fresh gas compressor Shaft Wastegate Cam housing Surface of the cam bearing Exhaust unit of the camshaft of the camshaft Post-treatment device Camshaft bearing surface of the bearing surface of the cam follower of the camshaft bearing surface of the camshaft post-treatment device of the camshaft bearing block of the bearing block of the cam bearing housing first lubricant channel second lubricant channel axis of rotation of the camshaft / of the cam piece mouth opening of a lubricant channel valve body valve seat

Claims

Claims

1. Plain bearing with a bearing housing (29) and a bearing piece which is rotatably and axially displaceable within a bearing opening (30) of the bearing housing (29) and which forms an outer bearing surface (33) which forms an inner bearing surface (32) of the bearing housing (29) a contact gap (34), characterized in that a first lubricant channel (35) and a second lubricant channel (36) for a supply of lubricant to the contact gap (34) are integrated in the bearing housing (29) or in the bearing piece, which axially at a distance from one another open into the inner bearing surface (32) or the outer bearing surface (33), with the supply of lubricant via the first lubricant channel (35) and the second lubricant channel (36) being able to be influenced by means of a distribution device, and the axial displaceability of the bearing piece relative to the bearing housing (29) is such that the outer bearing surface (33) of the bearing piece or the inner bearing surface (22) of the bearing housing (29)

- In a first sliding position of the sliding bearing, the mouth openings (38) of the first lubricant channel (35) and the second lubricant channel (36) are covered, and

- In a second sliding position of the sliding bearing, the mouth opening (38) of the first lubricant channel (35) covers and the mouth opening (38) of the second lubricant channel (36) releases and

- In a third sliding position of the sliding bearing, the mouth opening (38) of the first lubricant channel (35) releases and covers the mouth opening (38) of the second lubricant channel (36).

2. Plain bearing according to claim 1, characterized in that in the second sliding position and / or in the third sliding position of the plain bearing the outer bearing surface (33) of the bearing piece and the inner bearing surface (32) of the bearing housing (29) only partially overlap.

3. Plain bearing according to claim 1 or 2, characterized in that a valve body (39) is arranged in each of the lubricant channels (35, 36) which closes the respective lubricant channel (35, 36) when the associated mouth opening (38) is released , and which opens the respective lubricant channel (35, 36) when the associated mouth opening (38) is covered.

4. Plain bearing according to claim 3, characterized in that the valve body (39), when it closes the associated lubricant channel (35, 36), protrudes from the mouth opening (38) of this lubricant channel (35, 36).

5. Plain bearing according to one of the preceding claims, characterized in that the first lubricant channel (35) and the second lubricant channel (36) are integrally formed in at least one section.

6. Plain bearing according to one of the preceding claims, characterized in that the bearing piece is designed as a cam piece (27) and has at least three cam elevations (25) arranged axially offset from one another.

7. Plain bearing according to claim 6, characterized in that the radius of the outer bearing surface (33) of the cam piece (27) is greater than the largest radius of the cam elevations (25).

8. Plain bearing according to claim 6 or 7, characterized in that in the second and / or third sliding position at least one cam projection (25) is arranged at least partially within the bearing opening (30).

9. A valve drive for an internal combustion engine (1) characterized by a camshaft (18) which is mounted by means of at least one plain bearing according to one of claims 6 to 8 and which forms or encompasses the cam piece (27).

10. Valve drive according to claim 9, characterized in that the cam piece (27) is sleeve-shaped and rotatably and axially displaceably mounted on a base shaft (28) of the camshaft (18).

11. Internal combustion engine (1) with at least one combustion chamber (9), at least one gas exchange valve (12, 13) assigned to the combustion chamber (9), a valve drive according to claim 9 or 10 for actuating the gas exchange valve (12, 13) and an adjusting device (24 ), by means of which the cam piece (27) can be axially displaced in such a way that the cam elevations (25) can alternatively be brought into operative connection with the gas exchange valve (12, 13).