This disclosure relates to a hydraulic camshaft adjuster and a method for locking a rotor of a hydraulic camshaft adjuster.
Hydraulic camshaft adjusters are used in internal combustion engines to adapt the valve timing of the intake and exhaust valves to a corresponding load condition of the internal combustion engine and thus increase the efficiency thereof. State-of-the-art hydraulic camshaft adjusters are known to work according to the vane principle. The cam-shaft adjuster comprises of a stator and a rotor that can be rotated relative to the stator, wherein a working chamber is formed between the stator and the rotor, which is divided into two working chambers by a vane of the rotor. The position of the rotor relative to the stator can be changed by applying a suitable hydraulic pressure to the working chambers, which allows the control times of the valves to be adjusted. The rotor is usually adjustable between a retarded and an advanced position, which are defined by corresponding stops on the stator. In addition, hydraulic camshaft adjusters are known in which the rotor can be mechanically locked in a middle position between the two stops. Well-known are hydraulic camshaft adjusters, where such a middle locking is realized by two locking bolts, which can engage in two locking slotted guides. The disadvantage of such a solution, however, is that two locking slotted guides as well as two hydraulic supply channels must be formed on the rotor in order to supply the respective locking slotted guide having pressure medium for hydraulic release, which leads to a high production effort and correspondingly high production costs.
From US 2005/0 016 481 A1 a hydraulic camshaft adjuster is known, in which two locking elements can engage in a common locking slotted guide. Two spring-loaded locking elements are thus provided on the stator of the hydraulic camshaft adjuster, which engage in a locking slotted guide formed on a radially external surface of the rotor and can thus lock the rotor relative to the stator.
A hydraulic camshaft adjuster having locking mechanism is known from DE 102 17 062 A1, where the locking element is designed as a stepped locking bolt which can lock in a locking slotted guide. The locking bolt is arranged in the rotor and can lock in the axial direction in a locking slotted guide provided on a cover of the hydraulic camshaft adjuster.
The object of the disclosure is to reduce the complexity and thus the production costs of a hydraulic camshaft adjuster having two locking elements.
The object is achieved by a hydraulic camshaft adjuster for the variable adjustment of the control times of gas exchange valves of an internal combustion engine, having a stator and a rotor rotatable relative to the stator, having webs projecting radially inwards on the stator and vanes projecting radially outwards on the rotor. Several hydraulic working chambers are formed between the stator and rotor, each of which is divided by a rotor vane into a first working chamber and a second working chamber. Two locking elements are inserted into the rotor to lock the rotor in a middle position relative to the stator. It is intended that the first locking element and the second locking element can be locked in a common locking slotted guide. The proposed solution eliminates the need for a locking slotted guide compared to the solution known from the state of the art, so that simpler tools can be used to produce the locking slotted guide. In addition, less material must be removed, which reduces material wear and shortens the processing time. This reduces the production costs for the locking slotted guide. In addition, a pressure medium supply for a locking slotted guide, hereinafter also referred to as a C-channel, can be omitted on the rotor, which also reduces the production and tooling costs for the rotor.
Due to the features described herein and shown in the figures, further advantageous developments and improvements of the hydraulic camshaft adjuster are possible.
In one embodiment of the disclosure, it is provided that the locking slotted guide is formed as a stepped locking slotted guide, the locking slotted guide comprising at least a base, a middle step and a plateau, the middle step being arranged or formed between the base and the plateau. Despite a common locking slotted guide, the same number of steps for locking can be displayed as with a camshaft adjuster having two locking slotted guides. The multiple use of the locking steps in the locking slotted guide is realized in such a way that the two locking elements in the rotor are arranged very close to each other, so that one locking element can use the locking steps and stops of the other locking element in the locking slotted guide during adjustment.
In accordance with an advantageous design of the hydraulic camshaft adjuster, it is provided that both the first locking element and the second locking element are in contact with the base of the locking slotted guide when the rotor is locked in a middle position. This enables a stable and functionally reliable locking of the rotor in the middle position, as the locking elements only lift off the base when the locking slotted guide is pressurized through an appropriate hydraulic control. The control is preferably exerted through a pressure fluid pump and a central valve of the hydraulic camshaft adjuster as well as a C-channel, which connects the central valve with the locking slotted guide.
In one embodiment of the disclosure, it is provided that a first stop surface for the locking elements in the “advanced” direction and a second stop surface in the “retarded” direction are formed on the middle step. The middle step is wider than the base of the locking slotted guide. In this way, a staircase shape can be realized easily and cost-effectively in terms of production technology, against which the locking elements can rest in descending direction when turned to the middle position until the locking elements have reached the base of the locking slotted guide.
In one embodiment of the disclosure, it is provided that the locking slotted guide is formed or arranged in a locking cover of the hydraulic camshaft adjuster which limits the stator and rotor in the axial direction. A locking slotted guide in a cover can be produced easily and economically compared to a locking slotted guide in the stator or rotor. This can be achieved in particular by a forming process or a machining process, especially a milling process. Alternatively, it is possible to form the locking slotted guide by inserts which are inserted into, in particular pressed into a groove of the locking cover.
According to one embodiment of the disclosure, it is provided that the locking elements are designed as stepped locking elements, in particular as stepped locking bolts. Stepped locking elements allow both additional steps and additional functions to be implemented. The locking bolts can be in operational connection with the locking slotted guide in two different steps, once when the front face of the locking element is installed on the step and once when the locking bolt is supported on the step.
The stepped locking element can have a cylindrical base body with a diameter D1 and a projection with a diameter D2, preferably coaxial with the cylindrical base body, the diameter D1 of the cylindrical base body being greater than the diameter D2 of the projection. Such locking bolts can be produced simply and economically as turned parts or in a combination of a deep drawing process and a downstream turning process. As an alternative to a cylindrical bolt, the stepped locking element can also be designed in other shapes, for example as rectangular plates.
It is intended that a circumferential bearing surface is formed on the stepped locking elements at the transition from the cylindrical base body to the projection. An additional locking step can easily be formed by a circumferential projection, so that five instead of only three locking steps can be formed with the described locking slotted guide. The stepped locking element can rest on the plateau with the projection (1st step), rest on the plateau with the surrounding projection (2nd step), rest with the projection resting on the middle step (3rd step), rest with the perimeter projection resting on the middle step (4th step) or rest on the base with the projection (5th step). This allows smaller rotations with lower forces and/or lower torques to be used to turn the rotor step by step to the middle position.
Particular preference is given if the height of the middle step of the locking slotted guide and/or the height of the base is/are greater than the height of the projection on the stepped locking element. This ensures that there is sufficient space when the stepped locking element is present on the circumferential projection.
According to the disclosure, a method for locking a rotor of a hydraulic camshaft adjuster is provided, in which the locking elements successively penetrates into the locking slotted guide when the rotor is rotated from an adjustment position to the middle position, whereby a rotation of the rotor in the direction of the middle position is possible and a rotation of the rotor is blocked against the rotation to the middle position. Having two locking elements and only one common locking slotted guide for the two locking elements, it is possible to create a locking process that allows the advantages of the well-known locking process with two locking slotted guides at lower production costs.
In the following, the disclosure is explained by means of different embodiments with reference to the attached figures. Identical components or components with the same function are marked with the same reference symbols. Herein:
In summary, it can be stated that with a hydraulic camshaft adjuster 1 according to the disclosure, it is possible to lock the two locking elements 11, 12 in a common locking slotted guide 10. This reduces the production costs for both the locking cover 13 and the rotor 3, since only one C-channel is required for the pressure medium supply of the locking slotted guide 10, thus saving one C-channel on the rotor 3.
1 Hydraulic camshaft adjuster
2 Stator
3 Rotor
4 Web
5 Vane
6 Workspace
9 Drive gearing
10 Locking slotted guide
11 First locking element
12 Second locking element
13 Locking cover
14 Stepped locking element
15 Base body (of the first locking element)
16 Projection (of the first locking element)
17 Base body (of the second locking element)
18 Projection (of the second locking element)
19 Plateau of the locking slotted guide
20 Middle step of the locking slotted guide
21 Base of the locking slotted guide
22 Stop surface (in the “advanced” direction)
23 Stop surface (in the “retarded” direction)
24 Stop surface (in the “advanced” direction)
25 Stop surface (in the “retarded” direction)
26 Bearing surface (on the first locking element)
27 Bearing surface (on the second locking element)
28 First locking cover
29 Second locking cover
D1 Diameter of the cylindrical base body
D2 Diameter of the projection
H Projection height
T1 Height of the middle step
T2 Height of the base
Number | Date | Country | Kind |
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10 2018 104 401.1 | Feb 2018 | DE | national |
This application is the U.S. National Phase of PCT Application No. PCT/DE2019/100018 filed on Jan. 11, 2019 which claims priority to DE 10 2018 104 401.1 filed on Feb. 27, 2018, the entire disclosures of which are incorporated by reference herein.
Filing Document | Filing Date | Country | Kind |
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PCT/DE2019/100018 | 1/11/2019 | WO | 00 |