The invention relates to a device for changing the relative angular position of a camshaft with respect to a crankshaft of an internal combustion engine with a drive element driven by the crankshaft, wherein the drive element is mounted rotatable with respect to the camshaft, and wherein at least two hydraulic chambers are formed between the drive element and the camshaft. The hydraulic chambers are pressurized with a pressurized fluid in order to set a defined relative rotational position between the drive element and the camshaft. The device comprises a housing element, in which means for controlling the flow of the pressurized fluid are arranged, wherein a pressure reservoir having a pressure chamber for pressurized fluid is disposed on the housing element and wherein the basic form of the pressure reservoir is substantially cylindrical.
Camshaft adjustment devices, in particular hydraulic camshaft adjustment devices are well known in the state of the art. The hydraulic camshaft adjustment device comprises an impeller having blades molded in or arranged on. The blades are located in hydraulic chambers, which are formed in an outer rotor. By appropriately applying hydraulic fluid to the corresponding side of the hydraulic chambers an adjustment of the inner rotor (connected to the camshaft) relative to the outer rotor can be achieved between an “early stop” and a “late stop”. Thereby, the flow of hydraulic fluid is controlled by means of an electrically activated directional valve. The transmission of the rotary motion of the crankshaft to the outer rotor is performed by a gearwheel mounted non-rotatably to the outer rotor.
A camshaft adjustment device of the mentioned kind is known from the German patent application DE 39 29 619 A1. The adjustment of the relative rotational position between crankshaft and camshaft is also achieved by hydraulic means. To constantly provide hydraulic fluid of sufficient pressure, a pressure reservoir with substantially cylindrical form is arranged on a cover element. The pressure reservoir radially extends away from the housing element. Through an also radially extending connection bore between the cover element and the pressure reservoir pressurized fluid can be channeled to the pressure reservoir to move a spring-biased piston by one piston stroke. The pressurized fluid then is available to the pressure reservoir with predetermined pressure. As needed, pressurized fluid can be removed again, wherein the spring moves the piston and thus fluid pressure is kept at a constant rate.
One disadvantage of the described device is that the manufacturing effort for the cover element and the pressure reservoir is relatively high and a plurality of cutting operations is usually required until completion. A further disadvantage is that the described kind of construction causes a device with relatively huge dimensions, which can't always be put into practice due to limitedly available space.
It is an object of the present invention to provide a device of the previously described kind in such a way, that a more compact construction is achieved than the already known solution. Furthermore it is focused to provide a more cost-effective manufacturing of said device.
The present invention provides that the pressure reservoir is arranged on the housing element in such a manner that the cylindrical lateral face thereof abuts a lateral portion of the housing element, wherein at least one fluid connection is formed between the housing element and the pressure chamber of the pressure reservoir.
If further additional elements abut the actual cylindrical contour of the pressure reservoir basic structure, the defined cylindrical lateral face refers to the cylindrical lateral face of the pressure reservoir's basic form.
The pressure reservoir is preferably formed as a piston-cylinder system, wherein a piston is arranged movably in a cylinder element and wherein the piston is biased in the cylinder element by a spring element, in particular a coil spring.
The housing element and the housing of the pressure reservoir are preferably formed as one piece part. The housing element and the housing of the pressure reservoir are in particular cast parts. The housing element and the housing of the pressure reservoir are made of light metal, in particular aluminum.
Between the lateral region of the housing element and the pressure chamber of the pressure reservoir a fluid connection conduct can be arranged, that runs parallel to a direction of movement of the piston of the pressure reservoir to an axial end portion of the pressure reservoir. The length of the fluid connection line is preferably 50 percent of the overall height of the pressure reservoir.
An axial end portion of the pressure reservoir can be closed by a cover element. The cover element can have at least one flow path for the flow of pressurized fluid from the end of the fluid connection line to the pressure chamber. Alternatively or additionally it is possible to form the piston in such a manner that the flow of pressurized fluid from the end of the fluid connection conduct to the pressure chamber is enabled.
The cover element can be sealed by sealing elements at the pressure reservoir basic structure. The mounting can be realized in any given form, for instance with bolts, by welding or soldering, but also by an adhesive bond.
The piston can delimit the pressure chamber of the pressure reservoir to an equalization chamber, wherein a fluid connection (vent conduct) can be formed between the housing element and the equalization chamber of the pressure reservoir. The vent conduct can also be realized by a groove in the portion of the unpressurized side of the pressure reservoir.
Finally, means for limiting the axial movement of the piston in the cylinder element can be provided. This allows the prevention of driving the previously mentioned spring element to its hard stop.
The pressure reservoir can thus be arranged on the housing element in a simple manner, wherein it is possible to exactly define the ideal position of the pressure reservoir in the specific application.
The pressure reservoir can also be arranged slightly inclined to the cover element, if the circumstances concerning the available space require so.
Furthermore, the proposed arrangement is advantageous due to its relatively low weight.
The proposed concept is particularly advantageous to be realized by means of casting. It is thus possible and preferred to manufacture the housing element and the housing of the pressure reservoir in one piece. Cutting operations can thereby be reduced to a minimum and thus costs are reduced.
The proposed concept can generally be put into practice in every system that use hydraulic systems, for which a pressurized fluid has to be provided, wherefore a pressure reservoir is used.
In the following, an embodiment will explain the inventive device with reference to the accompanying drawings, in which
In the drawings a device for changing the relative angular position of a camshaft with respect to a crankshaft of an internal combustion engine, in other words, a camshaft adjustment device, is only partly displayed. It is shown a closing cover-like housing element 1, in which control means for controlling the flow of hydraulic oil in order to achieve an adjustment of the relative angular position between crankshaft and camshaft of the internal combustion engine can be housed.
This construction is basically known, wherefore reference is explicitly made to the German patent application DE 39 29 619 A1.
The displayed housing element 1 is mounted to the other assemblies of the camshaft adjustment device by means of a number of bolts. The other assemblies of the camshaft adjustment device have no importance for the present invention and are not displayed for this reason.
In order to constantly provide hydraulic fluid of sufficient pressure, a pressure reservoir 2 is arranged on the housing element 1. The pressure reservoir 2 has a pressure chamber 3, which has a variable volume and so various amounts of hydraulic fluid can be taken in. The pressure reservoir 2 is a piston-cylinder system, in other words, it has a piston 6, which is arranged in a cylinder element 7 and can be moved in a direction of movement V in the cylinder element 7.
The pressure reservoir 2 has a substantially cylindrical basic shape. The piston 6 thereby moves against the force of a spring element 8, which therefore prestresses the piston 6 and builds up the pressure in the pressurized fluid, which is channeled to the pressure reservoir.
It is essential that the pressure reservoir 2 is arranged at the housing element 1 in such a manner that the cylindrical lateral face 4 thereof abuts a lateral portion 5 of the housing element 1. Thereby at least one fluid connection is formed between the housing element 1 and the pressure chamber 3 of the pressure reservoir 2. If elements (for instance the following described connection duct 10) disturb the cylindrical from of the pressure reservoir 2, the defined cylindrical lateral face refers to the cylindrical lateral face of the cylinder, which is defined by the cylinder element 7.
The housing element 1 and the housing 9 of the pressure reservoir 2 are formed in one piece as cast part, preferably as an aluminum pressure cast part. All substantial functional surfaces and flow channels for the pressurized fluid and the venting of the system are integrated in the cast construction in order to reduce mechanical, cutting reworking.
In order to channel pressurized fluid from the housing element 1 to the pressure reservoir 2 and in particular to the pressure chamber 3 of the pressure reservoir 2, a fluid connection duct 10 is provided. It runs parallel to the direction of movement V in the lateral portion of the housing 9 of the pressure reservoir 2. The connection duct 10 has a length L greater than 50 percent of the overall height H of the pressure reservoir 2.
In view of all the the accompanying drawings in conjunction with each other it is apparent that pressurized fluid can be channeled by two fluid inlets 17—formed as holes in the connecting wall between the housing element 1 and the pressure reservoir 2—to the connection duct 10.
The pressurized fluid then goes up in the connection duct 10 and reaches the upper axial end portion 11 of the pressure reservoir 2, where a cover element 12 is fixed by bolts. A recess is formed in the cover element 12 and forms a flow path 13, so that pressurized fluid can flow from the connection duct 10 to the pressure chamber 3. When pressurized fluid enters, the piston 6 is pressed down against the force of the spring element 8.
Below the piston 6 is an equalization chamber 14, whose volume is reduced when pressurized fluid is entering the pressure chamber 3. A fluid connection 15 is provided for the venting of the equalization chamber 14.
In order to prevent the windings of the coil element 8 of being driven to its hard stop when the pressure chamber 3 is filled correspondingly with pressurized fluid, a defined stop for the lowest position of the piston 6 is provided in the cylinder element. It is marked by reference character 16. The stop is formed by a radial reduction of the bore diameter of the cylinder element 7 and therefore provides means for limiting the axial movement of the piston 6.
Number | Date | Country | Kind |
---|---|---|---|
10 2010 012 482 | Mar 2010 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2011/051802 | 2/8/2011 | WO | 00 | 11/19/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/117016 | 9/29/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5189999 | Thoma | Mar 1993 | A |
20100313834 | Auchter et al. | Dec 2010 | A1 |
20100326383 | Auchter et al. | Dec 2010 | A1 |
Number | Date | Country |
---|---|---|
39 29 619 | Mar 1991 | DE |
39 29 621 | Mar 1991 | DE |
4210580 | Oct 1993 | DE |
102006052998 | Jul 2008 | DE |
10 2007 056 683 | May 2009 | DE |
10 2007 056 685 | May 2009 | DE |
10 2008 015 137 | Oct 2009 | DE |
2 267 282 | Dec 2010 | EP |
2009-167842 | Jul 2009 | JP |
Number | Date | Country | |
---|---|---|---|
20130055979 A1 | Mar 2013 | US |