This claims the benefit of German Patent Application DE 10 2012 213 176.0, filed Jul. 26, 2012 and hereby incorporated by reference herein.
The present invention relates to a hydraulic camshaft phaser for an internal combustion engine, including an outer rotor and an inner rotor, the outer rotor and the inner rotor being rotationally adjustable and arranged concentrically about a common axis of rotation. At least one hydraulic chamber is formed between the outer rotor and the inner rotor, into which hydraulic chamber at least one connected vane extends from each of the outer rotor and the inner rotor, thereby dividing the hydraulic chamber into at least one pressure chamber pair formed by two pressure chambers. The inner rotor has a circular opening extending concentrically along the axis of rotation, a sealing portion being formed on the inner surface of the circular opening between two axial faces of the inner rotor, and the opening having a larger cross-sectional area on both sides of the sealing portion than in the sealing portion.
In internal combustion engines with mechanical valve actuation, gas exchange valves are actuated by the cams of a camshaft which is driven by a crankshaft, the valve timing being definable by the arrangement and the shape of the cams. The valve timing can be selectively controlled by varying the phase relationship between the crankshaft and the camshaft as a function of the instantaneous operating state of the internal combustion engine, which makes it possible to achieve advantageous effects, such as a reduction in fuel consumption and pollutant generation.
Devices for adjusting the phase relationship between the crankshaft and the camshaft are commonly known as camshaft phasers.
In general, camshaft phasers include a drive part which is drivingly connected to the crankshaft via a drive sprocket, and an output part which is fixed to the camshaft, as well as an adjusting mechanism which is connected between the drive part and the output part and transmits the torque from the drive part to the output part and which makes it possible to adjust and fix the phase relationship between the two.
In a conventional design as a hydraulic rotary actuator, the drive part is configured as an outer rotor and the output part is configured as an inner rotor, the outer rotor and inner rotor being rotationally adjustable and arranged concentrically about a common axis of rotation. In the radial space between the outer rotor and the inner rotor, at least one hydraulic chamber is formed by one of the two rotors, and a vane connected to the respective other rotor extends into the hydraulic chamber, thereby dividing it into a pair of oppositely acting pressure chambers. By selectively pressurizing the pressure chambers, the outer rotor and the inner rotor can be adjusted relative to each other, thereby varying the phase relationship between the crankshaft and the camshaft.
For purposes of pressurizing the oppositely acting pressure chambers, the inner rotor is typically provided with holes to which a pressurized hydraulic medium can be supplied through a central opening in the inner rotor. The two hydraulic circuits must be hydraulically separated from each other by suitable sealing measures. A hydraulic camshaft phaser of this type is known, for example, from DE 10 2009 014 338, in particular FIG. 4A and FIG. 4B thereof.
It is an object of the present invention to provide a camshaft phaser that is cost-effective to manufacture.
The present invention provides a hydraulic camshaft phaser for an internal combustion engine which includes an outer rotor and an inner rotor, the outer rotor and the inner rotor being rotationally adjustable and arranged concentrically about a common axis of rotation. At least one hydraulic chamber is formed between the outer rotor and the inner rotor, into which hydraulic chamber at least one connected vane extends from each of the outer rotor and the inner rotor, thereby dividing the hydraulic chamber into at least one pressure chamber pair formed by two pressure chambers. The inner rotor has a circular opening extending concentrically along the axis of rotation, a sealing portion being formed on the inner surface of the circular opening between two axial faces of the inner rotor, and the opening having a larger cross-sectional area on both sides of the sealing portion than in the sealing portion. In accordance with the present invention, the inner rotor is a sintered part, and the sealing portion of the inner rotor is calibrated.
The inner rotor of the camshaft phaser is shaped such that the inner rotor can be manufactured ready out-of-the-mold by the sintering process, which has a favorable effect on manufacturing cost. Thus, the inner rotor can be used in the camshaft phaser without having to be machined, at least in the region of the circular opening, which makes it possible to reduce the manufacturing effort and corresponding costs. This also allows the inner rotor to be manufactured with high process reliability, which reduces rejects and may thereby also reduce the manufacturing cost.
In this context, the term “calibrated” refers to a step in the manufacture of sintered components that may typically be performed subsequent to the sintering of the component, before the component is fully completed. Unlike other surfaces of the inner rotor, the radially inner surface of the sealing portion is subject to higher requirements in terms of dimensional accuracy and surface finish. Moreover, in the region of the sealing portion, higher demands are placed on the material strength near the surface. The calibration of the sealing portion of the inner rotor is performed using a special tool which represses the inner rotor in the region of the sealing portion, thereby making it possible to achieve improved surface finish, strength and dimensional accuracy for the sealing portion.
In an advantageous embodiment, a core assembly is disposed in the sealing portion of the circular opening. The core assembly is preferably rotatable with respect to the inner rotor and provides a substantially pressure-tight connection, whereby the two regions located outside the sealing portion on both sides thereof may form part of separate hydraulic circuits, and thus may be subjected to different pressures. In addition, the core assembly may be used to center and align the inner rotor.
The core assembly is preferably a central valve. By mounting a central valve in the circular opening of the inner rotor, a simple and especially compact design can be achieved for the camshaft phaser. This also results in short hydraulic paths from the central valve, which controls the camshaft phaser, to the pressure chambers, so that the camshaft phaser can be adjusted and controlled rapidly and accurately.
In an advantageous embodiment, a clearance fit is provided between the core assembly and the sealing portion. This allows for easy rotation of the core assembly, in particular a central valve, relative to the inner rotor, while at the same time allowing hydraulic separation of the two hydraulic circuits for the pressure chamber pairs. Thus, there is no need for additional means, such as a ball bearing, for rotatably supporting the core assembly in the inner rotor. The surface finish and dimensional accuracy required for a suitable clearance fit can be obtained in a cost-effective manner and without machining of the sealing portion by manufacturing the inner rotor using a sintering process, in particular by calibrating the sealing portion.
Preferably, the inner rotor and the vanes connected to the inner rotor form an integral component. This allows for a lighter-weight and inexpensive camshaft phaser. Integration of the vanes may be advantageous, in particular in the case of a sintered part.
In an advantageous embodiment, the sealing portion has a constant inside diameter. This enables an efficient and non-wearing seal to be made between a core component [core assembly] and the sealing portion, in particular during possible rotational movements between the inner rotor and the core assembly.
Preferably, the sealing portion is disposed symmetrically between the axial faces of the inner rotor. This allows uniform routing of forces in the inner rotor, which may have a positive effect on the life and resistance to wear of the inner rotor. Moreover, the sintering process and the preceding pressing operation can thereby be simplified.
Advantageously, the circular opening has equal diameters on both sides of the sealing portion. Equal diameters on both sides of the sealing portion can make it possible to obtain comparable pressure conditions in these regions, thereby enabling the pressure chambers of a pressure chamber pair to be hydraulically controlled in a comparable manner. This may also contribute to axial mountability, regardless of direction.
Further advantages and advantageous embodiments of the invention will be apparent from the following description, the figures, and the claims.
Other features of the invention may be derived from the following description of drawings, which illustrate preferred embodiments of the invention.
In the drawings:
In a typical exemplary embodiment (see also
1 camshaft phaser
2 outer rotor
3 inner rotor
4 axis of rotation
5 vane
6 pressure chamber
7 pressure chamber
8 circular opening
9 axial face
10 sealing portion
11 core assembly
104 camshaft
105 drive sprocket
106 outer ring
107 radial partition walls
108 end plate
109 end plate
110 rotor hub
112 axial screw
113 clamping bolt
114 bushing
115 rotary oil passage member
117 camshaft bearing
118 radial channels
119 radial channels
120 inner annular channel
121 outer annular channel
122 oil separation sleeve
123 radial bore
124 outer annular channel
125 radial bore
126 radial bore
127 locking pin
Number | Date | Country | Kind |
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DE102012213176.0 | Jul 2012 | DE | national |