CAMSHAFT ADJUSTER

Abstract

A camshaft adjuster for adjusting the phase position of a camshaft relative to a crankshaft, in particular a hydraulic camshaft adjuster. A camshaft bearing area provided in the camshaft adjuster is designed as a roller bearing.

Description

FIELD OF THE INVENTION

The invention relates to a camshaft adjuster of an internal combustion engine, in particular a hydraulic camshaft adjuster.

Nowadays, use is widely made of the hydraulic phase or camshaft adjuster, having an oscillating or rotary motor known from the field of hydraulics. Said oscillating motor phase adjuster is operated with engine oil pressure. The phase adjuster is conventionally situated on the ends of the camshaft in the power transmission path. The hydraulic camshaft adjuster is supplied with pressurized oil by means of the oil pump of the engine, Oil guiding ducts are provided in the camshaft for the supply to the actuator. By means of electronically controlled valves, the hydraulic oil is conveyed into the oil pressure chambers of the oscillating motor, and an adjustment of the phase position of the camshaft relative to the crankshaft is thereby attained. That side of the camshaft which faces toward the camshaft adjuster is mounted in a plain bearing on account of the hydraulic oil supply which is usually conducted through the camshaft. For the mounting of the camshaft at the end side, use is usually made of bushes or bearing blocks.

DE 100 02 512 A1 describes a cylinder head for a valve-controlled internal combustion engine, in which cylinder head are provided bearing seats for the inlet and outlet camshafts. On the side of the hydraulic camshaft adjuster, a bearing bush is provided in the bearing seat in order to compensate for the assembly recesses required in the bearing seat and to permit the supply of hydraulic oil to the camshaft adjuster in the bearing point. The hearing bush has two openings, which are arranged axially adjacent to one another, for the two-duct supply of oil to the camshaft adjuster, and a lubricant opening for the lubrication of the bearing point.

DE 10 2004 053 572 B4 describes a hydraulic camshaft adjuster having a two-duct oil guide in the camshaft. Two oil guiding ducts are provided within the camshaft, via which oil guiding ducts hydraulic oil is supplied to in each case one oil pressure chamber (depending on the desired adjusting direction). The oil guiding ducts extend through the camshaft and via external lines to an oil pump and an oil control valve.

DE 198 17 319 A1 describes a hydraulic camshaft adjuster in which a central control slide is provided in order to supply hydraulic oil to the working chambers of the vane-type adjuster. The central control slide replaces the external valve and is integrated, as a 4/2 directional control valve, into the central fastening screw for the camshaft, as a result of which only one radial oil guiding duct is required in the camshaft, and the axial structural length of the camshaft adjuster is reduced.

Various documents, such as for example DE 10 2005 059 841 A1 or DE 197 52 381 A1, are concerned inter alia with the lubrication of bearing points for camshafts.

Depending on the rotational speed range of the engine and the temperature, mechanical friction losses in the engine alone nowadays amount to up to 30 percent, and therefore account for a significant proportion of fuel consumption. The main sources of friction losses in the engine are the piston assemblies, the bearings of the engine shafts, and the valve drive components.

It is therefore the object of the invention to optimize a camshaft bearing point at the side of a hydraulic camshaft adjuster with regard to the occurring friction losses.

The object is achieved according to the invention by means of a camshaft adjuster having the features of claim 1.

According to the invention, in a hydraulic camshaft adjuster, a rolling bearing is arranged in a bearing point for a camshaft. The rolling bearing is preferably a ball bearing.

The advantages of the invention can be considered in particular to be that mechanical friction losses and undesired noise generation in the combustion engine can he further reduced.

The bearing point according to the invention of the camshaft can particularly advantageously be applied to a vane-type adjuster with a central supply of pressure medium by means of a control slide. By dispensing with a radial oil guiding duct in the camshaft, the installation space gained can be used for arranging a rolling bearing. The invention may however also be applied to camshaft adjusters with axial oil guiding ducts.

In another advantageous embodiment, the supply of hydraulic oil into the adjuster takes place at the side facing away from the camshaft. In this case, too, an oil guiding duct in the camshaft is not required, and this reduces the axial installation space and nevertheless allows the camshaft to be mounted using rolling bearings.

A preferred embodiment of the invention will be explained in more detail below on the basis of the figure, in which:

FIG. 1 shows a preferred embodiment of a camshaft adjuster according to the invention in a longitudinal sectional illustration.

FIG. 1 shows a camshaft adjuster 01. In a known way, the camshaft adjuster is designed as a vane-type adjuster and is arranged in the cylinder head of an internal combustion engine. Said camshaft adjuster comprises an outer rotor 02 which is connected to a sprocket 03 for conjoint rotation therewith.

The sprocket 03 is connected via a chain to a crankshaft, and is driven by the latter (not illustrated) during the operation of the internal combustion engine.

The camshaft adjuster 01 also comprises an inner rotor 04 which is connected to a camshaft 06 for conjoint rotation therewith. The fastening of the inner rotor 04 to the camshaft 06 is realized by means of a central screw 07.

Radially aligned vanes 08 which engage one into the other are provided on the outer rotor 02 and on the inner rotor 04, which vanes, in annular sectors, form in each case two pressure chambers 09 for the adjustment in the “early” and “late” directions. For adjustment, depending on the desired adjusting direction, hydraulic oil is pumped into one of the pressure chambers 09, as a result of which a relative rotation between the inner rotor 04 and outer rotor 02, and therefore an adjustment of the phase position of the camshaft 06 relative to the sprocket 03 and therefore relative to the crankshaft, takes place.

In the basic position—typically a “late” control time in the case of inlet valve adjustment and an “early” control time in the case of outlet valve adjustment—a locking element (not illustrated) locks the adjuster when the engine is shut down. During operation, said locking action is released hydraulically.

A control slide 11 is arranged in the central screw 07, coaxially with the longitudinal axis thereof. The control slide 11 can be moved axially by means of an actuating drive 12. The actuating drive 12 is preferably an actuating magnet which moves an armature 13.

The control slide 11, with its annular ducts 14 and with radial bores 16 in the central screw 07, forms a multi-way valve by means of which the flow of the hydraulic oil to one or the other pressure chamber 09 is controlled and an adjustment is thereby realized.

In the event of an axial movement of the control slide 11, therefore, the oil pressure is switched between the pressure chambers 09. The pressure chamber 09 in each case not charged with oil pressure is connected to the return line.

Ducts 17 are provided in the inner rotor 04, which ducts permit the flow of hydraulic oil from a radial duct 18 of the camshaft 06 via an axial duct 19 to the pressure chambers 09 via the control slide 11.

To fix a control time position, the control slide 11 is held by the force of a spring 21 in a basic position, in which the connections of all the ducts are separated from one another.

According to the invention, a rolling bearing 22 is preferably arranged adjacent to the radial duct 18 in the camshaft bearing point 23 of the cylinder head.

In another embodiment of the invention, the supply of hydraulic oil may take place via an axial duct in the camshaft 06. In this way, further installation space can be saved in the axial direction and the camshaft can nevertheless be mounted using rolling bearings.

The mounting, according to the invention, of the camshaft in a rolling bearing at the adjuster side may also be applied to other camshaft adjusters if the axial installation space is available.

LIST OF REFERENCE NUMERALS

01 Camshaft adjuster

02 Outer rotor

03 Sprocket

04 Inner rotor

05 -

06 Camshaft

07 Central screw

08 Vane

09 Pressure chamber

10 -

11 Control slide

12 Actuating drive

13 Armature

14 Annular duct

15 -

16 Radial bore

17 Duct

18 Radial duct

19 Axial duct

20 -

21 Spring

Claims

1-5. (canceled)

6. A camshaft adjuster for adjusting a phase position of a camshaft relative to a crankshaft, comprising: a camshaft bearing point having a rolling bearing for mounting the camshaft.

7. The camshaft adjuster as claimed in claim 6, wherein the rolling bearing is a ball bearing.

8. The camshaft adjuster as claimed in claim 6, wherein a hydraulic pressure medium adjusts the phase position of the camshaft.

9. The camshaft adjuster as claimed in claim 8, further comprising a central control slide and a single radial duct arranged in the camshaft and connected to a pressure medium supply, the control slide and the single radial duct being in communication so as to supply the pressure medium for the phase position adjustment of the camshaft.

10. The camshaft adjuster as claimed in claim 8, wherein the camshaft has a radial duct formed between the camshaft adjuster and the bearing point in an axial direction, and the hydraulic pressure medium is supplied to the camshaft adjuster via the radial duct.