The present invention relates to a camshaft phaser.
Camshaft phasers are generally used in valve actuation systems of internal combustion engines to vary the valve opening and closing times, thereby making it possible to improve the fuel consumption figures of the internal combustion engine and the general operating characteristics.
One camshaft phaser design that has proven suitable in practice features a vane-type phaser having a stator and a rotor defining an annular space which is divided by projections and vanes into a plurality of working chambers. The working chambers can be selectively pressurized with a pressure medium which is fed by a pressure medium pump in a pressure medium circuit from a pressure medium reservoir into the working chambers on one side of the vanes of the rotor, and returned to the pressure medium reservoir from the working chambers on the respective other side of the vanes. The working chambers whose volume is thereby increased have a direction of action opposite to that of the working chambers whose volume is decreased. The direction of action accordingly means that pressurizing one of the groups of working chambers with pressure medium causes the rotor to rotate in a corresponding clockwise or counterclockwise direction relative to the stator. The flow of pressure medium, and thus the adjusting movement of the camshaft phaser, is controlled, for example, by a central valve having a complex system of flow passages and control edges and a valve body displaceable within the central valve to close or clear the passage openings as a function of its position.
One problem of such camshaft phasers is that, during a starting phase, they are not yet completely filled with pressure medium, or may even have run empty, so that the rotor may perform uncontrolled movements relative to the stator as a result of the alternating torques exerted by the camshaft. Such uncontrolled movements may lead to increased wear and unwanted noise generation. To avoid this problem, it is known to provide a locking device between the rotor and the stator. When the internal combustion engine is stopped, this locking device locks the rotor relative to the stator in an angular position that is favorable for the starting procedure. In exceptional cases, for example when the engine stalls, it may happen that the locking device does not lock the rotor as intended, and that the camshaft phaser must be operated with the rotor unlocked during the following starting phase. However, since some internal combustion engines have very poor starting performance when the rotor is not locked in the central position, the rotor must then be automatically rotated to the central locking position and locked during the starting phase.
Such automatic rotation and locking of the rotor relative to stator is known, for example, from DE 10 2008 011915 A1 and DE 10 2005 011 916 A1. Both of the locking devices described therein include a plurality of spring-loaded locking pins, which successively lock in locking slots provided in the sealing cover or the stator during a rotation of the rotor. Before the central locking position is reached, the respective locking pins permit rotation of the rotor in a direction toward the central locking position, but inhibit rotation of the rotor in the opposite direction. After the internal combustion engine has warmed up and/or after the camshaft phaser has been completely filled with pressure medium, the locking pins are urged out of the locking slots under the action of the pressure medium, so that the rotor can then be rotated as intended to adjust the angular position of the camshaft relative to the stator.
A disadvantage of this approach is that the locking of the rotor can only be accomplished with a plurality of successively locking locking pins, which results in higher costs. Further, the locking operation requires that the locking pins reliably lock successively. If one of the locking pins does not lock, the locking operation may be interrupted because the rotor is consequently not unidirectionally locked in the intermediate position and may rotate back.
It is an object of the present invention to provide a camshaft phaser having reliable and inexpensive means for locking the rotor in a central position.
The present invention provides at least one locking pin be provided with a blocking portion and a flow-through pressure medium conduit, by which a fluid connection between two working chambers of different directions of action can be established or blocked in the different positions of the first locking pin, and that the working chambers of the different directions of actions be capable of being short-circuited by a switching device, and that at least one pressure medium conduit which is fluidically connectable to the pressure medium circuit by the flow-through pressure medium conduit of the locking pin have a check valve therein which allows the pressure medium to flow into one of the working chambers whose volume is increased during a rotation of the rotor from either of the advance or retard stop positions toward the central locking position, while at the same time preventing backflow from the same working chamber.
The solution proposed herein allows the rotor to rotate in one direction relative to the stator utilizing the alternating torques (Camshaft Torque Actuated, CTA) acting on the camshaft during the starting phase of the internal combustion engine, while rotation in the respective other direction is blocked by the respective check valve. In this way, a kind a freewheel device is implemented, which enables the rotor to automatically rotate from an advance or retard stop position toward the central locking position until it is finally locked in the central locking position. In order to prevent the movement of the rotor from being impeded at the same time by the pressure medium in the other working chambers, these are short-circuited by the switching device that is provided. The check valve is deliberately disposed in a pressure medium conduit leading to the working chamber, which avoids the need to modify the rotor or the stator in the region of the pressure chambers.
It is also proposed to provide a flow-through pressure medium conduit in each of the two locking pins, and to provide two check valves in different pressure medium conduits which are connectable to the pressure medium circuit via the flow-through pressure medium conduits of the locking pins, the check valves being oriented to allow the pressure medium to flow into working chambers of different directions of action and to prevent backflow from the same working chambers.
Further, it is proposed that, in a first position, the locking pin(s) allow the pressure medium to flow to the check valve(s) via the flow-through pressure medium conduit and that, in a second position, the locking pin(s) prevent such flow via blocking portions, and that the locking pin(s) be spring-loaded in a direction toward the first position. In accordance with the proposed solution, the locking pins are automatically urged into the first position when the internal combustion engine is stopped, provided they are located relative to the locking slot in a suitable position which makes this possible. Thus, during the starting phase of the internal combustion engine, the pressure medium can immediately flow into the respective working chamber utilizing the alternating camshaft torques, and suitably rotate the rotor so as to return it to the central locking position.
Still further, it is proposed that the switching device for short-circuiting the working chambers take the form of a multi-way control valve controlling the inflow and outflow of the pressure medium from or into a pressure medium reservoir. The multi-way control valve, also referred to as central valve, is a proven component for controlling the adjusting movement of the rotor. In accordance with the proposed solution, this multi-way control valve is additionally used to control the short-circuiting between the working chambers, the multi-way control valve also controlling the locking and releasing movements of the locking pins and the flow of pressure medium into and out of the working chambers.
It is also proposed that the rotor have one or more partial ring-shaped or ring-shaped pressure medium conduit(s) provided therein into which open at least some of the pressure medium conduits leading to the working chambers. The solution proposed herein makes it possible to achieve a readily producible routing configuration of the pressure medium conduits, which in particular allows a plurality of working chambers of one direction of action to be short-circuited to a group of working chambers of a different direction of action via a single switching device.
The present invention will now be described in more detail by way of an exemplary embodiment. In the drawings,
In
Also shown is a pressure medium circuit having a plurality of pressure medium conduits 1,3,4,6,8,13,14,15,18,27,28, 29 and 30, which are selectively fluidically connectable via multi-way control valve 7 to pressure medium pump P or pressure medium reservoir T.
Stator 16 has a plurality of stator lobes dividing an annular space between stator 16 and rotor 17 into pressure chambers 24 and 25. Pressure chambers 24 and 25 are in turn divided by vanes 11 and 12 of rotor 17 into working chambers 20,21,22 and 23 into which open pressure medium conduits 1,3,4 and 6. Central-position locking device 26 includes two locking pins 2 and 5, which lock in a locking slot 19 stationary with respect to the stator in order to lock rotor 17 relative to stator 16. Locking slot 19 may be provided, for example, in a sealing cover threaded to stator 16.
Basically, the phase angle of the camshaft relative to the crankshaft is shifted, for example, in the advance direction, by pressurizing working chambers 20 and 22 with pressure medium, thereby increasing their volume, while at the same time displacing the pressure medium from working chambers 21 and 23, thereby decreasing their volume. In the figures, the advance stop position is denoted by F, and the retard stop position is denoted by S. In the context of the present invention, the working chambers 20,21,22 and 23 whose volume is increased in groups during this adjusting movement are referred to as working chambers 20,21,22 and 23 of one direction of action, while the working chambers 20,21,22 and 23 whose volume is at the same time decreased are referred to as working chambers 20,21,22 and 23 of the opposite direction of action. The change in the volume of working chambers 20,21,22 and 23 then causes rotor 17 to be rotated with its vanes 11 and 12 relative to stator 16.
In the approach of the present invention, locking pins 2 and 5 each have a flow-through pressure medium conduit 13 and 14 and blocking portions 31 and 32 provided therein, respectively. Locking pins 2 and 5 are spring-loaded toward a first position in which they engage in locking slot 19, as can be seen by locking pin 2 in
During the starting phase of the internal combustion engine, alternating torques act on the camshaft, and thus also on rotor 17. As a result of the torques acting on rotor 17 in the direction of the arrow in
In
Pressure medium conduits 1,3,4 and 6 leading to working chambers 20,21,22 and 23 each open into partial ring-shaped or ring-shaped pressure medium conduits 27 and 30, which are fluidically connected to the A- or B-port of multi-way control valve 7, either indirectly via pressure medium conduit 28 or, in the case of pressure medium conduit 27, directly. Further, pressure medium conduit 27 is connected directly to pressure medium conduit 14 in locking pin 2, and pressure medium conduit 30 is connected indirectly via pressure medium conduit 15 to pressure medium conduit 13 of locking pin 5. Moreover, pressure medium conduits 8 and 29 are connected by check valves 9 and 10 disposed therein to pressure medium conduits 27 and 30. Thus, pressure medium conduits 27 and 30 constitute collecting conduits into which is fed the pressure medium from the two working chambers 20 and 22 of decreasing volume, and from which the pressure medium is then removed and fed into working chambers 21 and 23 of increasing volume. It is important that the inflow of pressure medium be equal to the outflow of pressure medium in terms of volume so as not to hinder rotation of rotor 17.
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Number | Date | Country | Kind |
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10 2013 207 617.7 | Apr 2013 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/DE2014/200053 | 2/11/2014 | WO | 00 |